Blockchain-based judgment execution

ABSTRACT

Disclosed herein are methods, systems, and apparatus, including computer programs encoded on computer storage media. One method includes: receiving a request associated with an account of a blockchain-based application for collecting a monetary award issued in an order of a court; determining a creditor, a debtor, and an amount of the monetary award; determining that the account is associated with the creditor based on data recorded on the blockchain; identifying, based on the data, a payment account of the creditor and one or more payment accounts of the debtor with an aggregated balance greater than or equal to the amount of the monetary award; transferring the amount of the monetary award from the one or more payment accounts of the debtor to the payment account of the creditor; and recording a verified time stamp representing a time the amount of the monetary award is transferred.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/921,546, filed on Jul. 6, 2020, which is a continuation of U.S.patent application Ser. No. 16/714,379, filed on Dec. 13, 2019, now U.S.Pat. No. 10,783,597, issued Sep. 22, 2020, which is a continuation ofPCT Application No. PCT/CN2019/100258, filed on Aug. 12, 2019, eachapplication is hereby incorporated by reference in its entirety.

TECHNICAL FIELD

This specification relates to blockchain-based trusted platforms forenabling judgment execution.

BACKGROUND

Distributed ledger systems (DLSs), which can also be referred to asconsensus networks, and/or blockchain networks, enable participatingentities to securely, and immutably store data. DLSs are commonlyreferred to as blockchain networks without referencing any particularuser case. Examples of types of blockchain networks can include publicblockchain networks, private blockchain networks, and consortiumblockchain networks. A consortium blockchain network is provided for aselect group of entities, which control the consensus process, andincludes an access control layer.

Digital networks have enabled people around the world to findinformation and interact with each other conveniently and efficiently.For example, social media platforms allow people to easily sharemessages, photos, and videos with friends and colleagues. Onlineshopping web sites allow consumers to easily find information on avariety of products and send payments electronically to purchaseproducts from businesses all over the world. News web sites provideusers with up-to-date information about events happening around theworld. Media platforms provide a large collection of music and moviesfor users to download or stream online. Users can search for legalservices online. Ride hailing platforms allow riders to easily find andpay for transportation using mobile phones. As more people are connectedto the Internet and more transactions are conducted digitally, thenumber of fraudulent online activities and disputes between parties ofdigital transactions also increase.

It would be desirable to allow users to submit evidence related toonline digital transactions to court systems in a convenient manner.

SUMMARY

This specification describes technologies for enabling trustedtransactions. These technologies generally involve: providing, by ablockchain-based trusted platform, a service to a user in a plurality ofsteps; for each step of the plurality of steps, performing at least oneof obtaining a verified time stamp from a trusted timing module of thetrusted platform, obtaining a verified identity from a trusted identitymodule of the trusted platform, or obtaining a computation result from atrusted computing module of the trusted platform; and recording dataassociated with the service provided to the user and at least one of theverified time stamp, the verified identity, or the computation resultassociated with the step in a blockchain.

This specification also describes technologies for facilitating serviceof processes. These technologies generally involve: receiving a requestgenerated based on a blockchain-based application for delivering anotice associated with a legal action from a serving party to a party tobe served, wherein the request comprises an identity associated with theserving party and an identity associated with the party to be served;determining that the serving party is a registered user of theblockchain-based application based on matching the identity of theserving party with an identity included in registration information ofthe serving party recorded on a blockchain; recording a time that therequest is received on the blockchain; determining whether the party tobe served is a registered user of the blockchain-based application basedon the identity associated with the party to be served; in response todetermining that the party to be served is a registered user,identifying one or more manners of delivering the notice based onavailable communication methods included in the registration informationof the serving party and registration information of the party to beserved; and delivering the notice to the party to be served based on atleast one of the one or more manners.

This specification also describes technologies for legal documentation.These technologies generally involve: receiving a request for providinga service initiated from an account of a user associated with ablockchain-based application, wherein the request comprises an identityassociated with the user; determining that the user is a registered userof the blockchain-based application based on matching the identity withan identity included in registration information of the user associatedwith the blockchain-based application and recorded on a blockchain;identifying one or more electronic forms to be filled out and submittedin a plurality of steps for providing the service; at each step of theplurality of steps: generating a unique identifier (ID) based on a timethat the step is performed and digital content on the electronic form atthe time; recording the unique ID, the time, and the digital content onthe blockchain; embedding the unique ID in the digital content at thetime by changing one or more attributes associated with the digitalcontent to be representative of the unique ID, wherein the embeddingproduces information-embedded digital content that enables retrieval ofthe time and the digital content from the blockchain based on the uniqueID; and recording the information-embedded digital content to theblockchain.

This specification also describes technologies for dispute resolution.These technologies generally involve: at a blockchain-based application,receiving a request for resolving a dispute between at least a firstparty and a second party, wherein the request comprises a first identityassociated with the first party and a second identify associated withthe second party; determining that the first party and the second partyare registered users of the blockchain-based application based onmatching the first identity with an identity included in registrationinformation of the first party recorded on a blockchain and matching thesecond identity with an identity included in registration information ofthe second party recorded on the blockchain; recording a time that therequest is received on the blockchain; receiving one or more potentialdispute solutions from one or more dispute solution providers that areregistered on the blockchain-based application; receiving a firstselection from the first party and a second selection from the secondparty, wherein the first selection comprises a first set of the one ormore potential dispute solutions and the second selection comprises asecond set of the one or more potential dispute solutions; recording atime that the first selection is received on the blockchain and a timethat the second selection is received on the blockchain; and determiningat least one of (i) at least one common potential dispute solutionbetween the first set of the one or more potential dispute solutions andthe second set of the one or more potential dispute solutions, or (ii)that none of the potential dispute solutions are acceptable to the firstand second parties.

This specification also describes technologies for handling courtordered judgment. These technologies generally involve: receiving arequest associated with an account of a blockchain-based application forcollecting a monetary award issued in an order of a court, wherein therequest comprises an identity associated with the account; determining,by a trusted identity module, that the order is authentic based onmatching with a hash value associated with the order recorded on ablockchain; recording, by a trusted timing module, a first verified timestamp representing a time the request is received on the blockchain;invoking the trusted computing module to determine, based on parsing theorder, a creditor of the monetary award, a debtor of the monetary award,and an amount of the monetary award; determining, based on the trustedidentity module, that the account is associated with the creditor basedon the identity and registration information of the account recorded onthe blockchain; invoking the trusted computing module to identify, basedon the registration information, a payment account of the creditor andone or more payment accounts of the debtor with an aggregated balancegreater than or equal to the amount of the monetary award; invoking thetrusted computing module to transfer the amount of the monetary awardfrom the one or more payment accounts of the debtor to the paymentaccount of the creditor; and recording, by the trusted timing module, asecond verified time stamp representing a time the amount of themonetary award is transferred.

This specification further provides a system for implementing themethods provided herein. The system includes one or more processors, anda computer-readable storage medium coupled to the one or more processorshaving instructions stored thereon which, when executed by the one ormore processors, cause the one or more processors to perform operationsin accordance with embodiments of the methods provided herein.

It is appreciated that methods in accordance with this specification mayinclude any combination of the aspects and features described herein.That is, methods in accordance with this specification are not limitedto the combinations of aspects and features specifically describedherein, but also include any combination of the aspects and featuresprovided.

The details of one or more embodiments of this specification are setforth in the accompanying drawings and the description below. Otherfeatures and advantages of this specification will be apparent from thedescription and drawings, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating an example of an environment that canbe used to execute embodiments of this specification.

FIG. 2 is a diagram illustrating an example of an architecture inaccordance with embodiments of this specification.

FIG. 3 is a diagram illustrating an example of a blockchain-basedtrusted platform in accordance with embodiments of this specification.

FIG. 4 is a diagram illustrating an example of a system for collectingevidence in accordance with embodiments of this specification.

FIG. 5 is a diagram illustrating an example of a system for providingtrusted timing in accordance with embodiments of this specification.

FIG. 6 is a diagram illustrating an example of a system for providingtrusted identity in accordance with embodiments of this specification.

FIG. 7 is a diagram illustrating an example of a system for providingservice of process in accordance with embodiments of this specification.

FIG. 8 is a diagram illustrating another example of a system forproviding service of process in accordance with embodiments of thisspecification.

FIG. 9 is a flowchart illustrating an example of a process in accordancewith embodiments of this specification.

FIG. 10 is a diagram illustrating an example of a system for providinglegal documentation in accordance with embodiments of thisspecification.

FIG. 11 is a flowchart illustrating another example of a process inaccordance with embodiments of this specification.

FIG. 12 is a diagram illustrating an example of a system for providingdispute resolution in accordance with embodiments of this specification.

FIG. 13 is a flowchart illustrating another example of a process inaccordance with embodiments of this specification.

FIG. 14 is a diagram illustrating an example of a system for judgmentexecution in accordance with embodiments of this specification.

FIG. 15 is a flowchart illustrating yet another example of a process inaccordance with embodiments of this specification.

FIG. 16 is a flowchart illustrating yet another example of a process inaccordance with embodiments of this specification.

FIG. 17 depicts examples of modules of an apparatus in accordance withembodiments of this specification.

FIG. 18 depicts examples of modules of another apparatus in accordancewith embodiments of this specification.

FIG. 19 depicts examples of modules of yet another apparatus inaccordance with embodiments of this specification.

FIG. 20 depicts examples of modules of yet another apparatus inaccordance with embodiments of this specification.

FIG. 21 depicts examples of modules of yet another apparatus inaccordance with embodiments of this specification.

Like reference numbers and designations in the various drawings indicatelike elements.

DETAILED DESCRIPTION

This specification describes technologies for enabling trustedtransactions. These technologies generally involve: providing, by ablockchain-based trusted platform, a service to a user in a plurality ofsteps; for each step of the plurality of steps, performing, based on aprocessing of blockchain data using a trusted computing module of thetrusted platform, at least one of obtaining a verified time stamp from atrusted timing module of the trusted platform, obtaining a verifiedidentity from a trusted identity module of the trusted platform, orobtaining a computation result, and recording data associated with theservice provided to the user and at least one of the verified timestamp, the verified identity, or the computation result associated withthe step.

This specification also describes technologies for facilitating serviceof processes. These technologies generally involve: receiving a requestgenerated based on a blockchain-based application for delivering anotice associated with a legal action from a serving party to a party tobe served, wherein the request comprises an identity associated with theserving party and an identity associated with the party to be served;determining that the serving party is a registered user of theblockchain-based application based on matching the identity of theserving party with an identity included in registration information ofthe serving party recorded on a blockchain; recording a time that therequest is received on the blockchain; determining whether the party tobe served is a registered user of the blockchain-based application basedon the identity associated with the party to be served; in response todetermining that the party to be served is a registered user,identifying one or more manners of delivering the notice based onavailable communication methods included in the registration informationof the serving party and registration information of the party to beserved; and delivering the notice to the party to be served based on atleast one of the one or more manners.

This specification also describes technologies for legal documentation.These technologies generally involve: receiving a request for providinga service initiated from an account of a user associated with ablockchain-based application, wherein the request comprises an identityassociated with the user; determining that the user is a registered userof the blockchain-based application based on matching the identity withan identity included in registration information of the user associatedwith the blockchain-based application and recorded on a blockchain;identifying one or more electronic forms to be filled out and submittedin a plurality of steps for providing the service; at each step of theplurality of steps: generating a unique identifier (ID) based on a timethat the step is performed and digital content on the electronic form atthe time; recording the unique ID, the time, and the digital content onthe blockchain; embedding the unique ID in the digital content at thetime by changing one or more attributes associated with the digitalcontent to be representative of the unique ID, wherein the embeddingproduces information-embedded digital content that enables retrieval ofthe time and the digital content from the blockchain based on the uniqueID; and recording the information-embedded digital content to theblockchain.

This specification also describes technologies for dispute resolution.These technologies generally involve: at a blockchain-based application,receiving a request for resolving a dispute between at least a firstparty and a second party, wherein the request comprises a first identityassociated with the first party and a second identify associated withthe second party; determining that the first party and the second partyare registered users of the blockchain-based application based onmatching the first identity with an identity included in registrationinformation of the first party recorded on a blockchain and matching thesecond identity with an identity included in registration information ofthe second party recorded on the blockchain; recording a time that therequest is received on the blockchain; receiving one or more potentialdispute solutions from one or more dispute solution providers that areregistered on the blockchain-based application; receiving a firstselection from the first party and a second selection from the secondparty, wherein the first selection comprises a first set of the one ormore potential dispute solutions and the second selection comprises asecond set of the one or more potential dispute solutions; recording atime that the first selection is received on the blockchain and a timethat the second selection is received on the blockchain; and determiningat least one of (i) at least one common potential dispute solutionbetween the first set of the one or more potential dispute solutions andthe second set of the one or more potential dispute solutions, or (ii)that none of the potential dispute solutions are acceptable to the firstand second parties.

This specification also describes technologies for handling courtordered judgment. These technologies generally involve: receiving arequest associated with an account of a blockchain-based application forcollecting a monetary award issued in an order of a court, wherein therequest comprises an identity associated with the account; determining,by a trusted identity module, that the order is authentic based onmatching with a hash value associated with the order recorded on ablockchain; recording, by a trusted timing module, a first verified timestamp representing a time the request is received on the blockchain;invoking the trusted computing module to determine, based on parsing theorder, a creditor of the monetary award, a debtor of the monetary award,and an amount of the monetary award; determining, based on the trustedidentity module, that the account is associated with the creditor basedon the identity and registration information of the account recorded onthe blockchain; invoking the trusted computing module to identify, basedon the registration information, a payment account of the creditor andone or more payment accounts of the debtor with an aggregated balancegreater than or equal to the amount of the monetary award; invoking thetrusted computing module to transfer the amount of the monetary awardfrom the one or more payment accounts of the debtor to the paymentaccount of the creditor; and recording, by the trusted timing module, asecond verified time stamp representing a time the amount of themonetary award is transferred.

To provide further context for embodiments of this specification, and asintroduced above, distributed ledger systems (DLSs), which can also bereferred to as consensus networks (e.g., made up of peer-to-peer nodes),and blockchain networks, enable participating entities to securely, andimmutably conduct transactions, and store data. Although the termblockchain is generally associated with particular networks, and/or usecases, blockchain is used herein to generally refer to a DLS withoutreference to any particular use case.

A blockchain is a data structure that stores transactions in a way thatthe transactions are immutable. Thus, transactions recorded on ablockchain are reliable and trustworthy. A blockchain includes one ormore blocks. Each block in the chain is linked to a previous blockimmediately before it in the chain by including a cryptographic hash ofthe previous block. Each block also includes a timestamp, its owncryptographic hash, and one or more transactions. The transactions,which have already been verified by the nodes of the blockchain network,are hashed and encoded into a Merkle tree. A Merkle tree is a datastructure in which data at the leaf nodes of the tree is hashed, and allhashes in each branch of the tree are concatenated at the root of thebranch. This process continues up the tree to the root of the entiretree, which stores a hash that is representative of all data in thetree. A hash purporting to be of a transaction stored in the tree can bequickly verified by determining whether it is consistent with thestructure of the tree.

Whereas a blockchain is a decentralized or at least partiallydecentralized data structure for storing transactions, a blockchainnetwork is a network of computing nodes that manage, update, andmaintain one or more blockchains by broadcasting, verifying andvalidating transactions, etc. As introduced above, a blockchain networkcan be provided as a public blockchain network, a private blockchainnetwork, or a consortium blockchain network. Embodiments of thisspecification are described in further detail herein with reference to aconsortium blockchain network. It is contemplated, however, thatembodiments of this specification can be realized in any appropriatetype of blockchain network.

In general, a consortium blockchain network is private among theparticipating entities. In a consortium blockchain network, theconsensus process is controlled by an authorized set of nodes, which canbe referred to as consensus nodes, one or more consensus nodes beingoperated by a respective entity (e.g., a financial institution,insurance company). For example, a consortium of ten (10) entities(e.g., financial institutions, insurance companies) can operate aconsortium blockchain network, each of which operates at least one nodein the consortium blockchain network.

In some examples, within a consortium blockchain network, a globalblockchain is provided as a blockchain that is replicated across allnodes. That is, all consensus nodes are in perfect state consensus withrespect to the global blockchain. To achieve consensus (e.g., agreementto the addition of a block to a blockchain), a consensus protocol isimplemented within the consortium blockchain network. For example, theconsortium blockchain network can implement a practical Byzantine faulttolerance (PBFT) consensus, described in further detail below.

FIG. 1 is a diagram illustrating an example of an environment 100 thatcan be used to execute embodiments of this specification. In someexamples, the environment 100 enables entities to participate in aconsortium blockchain network 102. The environment 100 includescomputing devices 106, 108, and a network 110. In some examples, thenetwork 110 includes a local area network (LAN), wide area network(WAN), the Internet, or a combination thereof, and connects web sites,user devices (e.g., computing devices), and back-end systems. In someexamples, the network 110 can be accessed over a wired and/or a wirelesscommunications link. In some examples, the network 110 enablescommunication with, and within the consortium blockchain network 102. Ingeneral the network 110 represents one or more communication networks.In some cases, the computing devices 106, 108 can be nodes of a cloudcomputing device (not shown), or each computing device 106, 108 can be aseparate cloud computing device including a number of computersinterconnected by a network and functioning as a distributed processingsystem.

In the depicted example, the computing devices 106, 108 can each includeany appropriate computing device that enables participation as a node inthe consortium blockchain network 102. Examples of computing devicesinclude, without limitation, a server, a desktop computer, a laptopcomputer, a tablet computing device, and a smartphone. In some examples,the computing devices 106, 108 host one or more computer-implementedservices for interacting with the consortium blockchain network 102. Forexample, the computing device 106 can host computer-implemented servicesof a first entity (e.g., user A), such as a transaction managementsystem that the first entity uses to manage its transactions with one ormore other entities (e.g., other users). The computing device 108 canhost computer-implemented services of a second entity (e.g., user B),such as a transaction management system that the second entity uses tomanage its transactions with one or more other entities (e.g., otherusers). In the example of FIG. 1, the consortium blockchain network 102is represented as a peer-to-peer network of nodes, and the computingdevices 106, 108 provide nodes of the first entity, and second entityrespectively, which participate in the consortium blockchain network102.

FIG. 2 depicts an example of an architecture 200 in accordance withembodiments of this specification. The example conceptual architecture200 includes participant systems 202, 204, 206 that correspond toParticipant A, Participant B, and Participant C, respectively. Eachparticipant (e.g., user, enterprise) participates in a blockchainnetwork 212 provided as a peer-to-peer network including a plurality ofnodes 214, at least some of which immutably record information in ablockchain 216. Although a single blockchain 216 is schematicallydepicted within the blockchain network 212, multiple copies of theblockchain 216 are provided, and are maintained across the blockchainnetwork 212, as described in further detail herein.

In the depicted example, each participant system 202, 204, 206 isprovided by, or on behalf of Participant A, Participant B, andParticipant C, respectively, and functions as a respective node 214within the blockchain network. As used herein, a node generally refersto an individual system (e.g., computer, server) that is connected tothe blockchain network 212, and enables a respective participant toparticipate in the blockchain network. In the example of FIG. 2, aparticipant corresponds to each node 214. It is contemplated, however,that a participant can operate multiple nodes 214 within the blockchainnetwork 212, and/or multiple participants can share a node 214. In someexamples, the participant systems 202, 204, 206 communicate with, orthrough the blockchain network 212 using a protocol (e.g., hypertexttransfer protocol secure (HTTPS)), and/or using remote procedure calls(RPCs).

Nodes 214 can have varying degrees of participation within theblockchain network 212. For example, some nodes 214 can participate inthe consensus process (e.g., as miner nodes that add blocks to theblockchain 216), while other nodes 214 do not participate in theconsensus process. As another example, some nodes 214 store a completecopy of the blockchain 216, while other nodes 214 only store copies ofportions of the blockchain 216. For example, data access privileges canlimit the blockchain data that a respective participant stores withinits respective system. In the example of FIG. 2, the participant systems202, 204, and 206 store respective, complete copies 216′, 216″, and216′″ of the blockchain 216.

A blockchain (e.g., the blockchain 216 of FIG. 2) is made up of a chainof blocks, each block storing data. Examples of data include transactiondata representative of a transaction between two or more participants.While transactions are used herein by way of non-limiting example, it iscontemplated that any appropriate data can be stored in a blockchain(e.g., documents, images, videos, audio). Examples of a transaction caninclude, without limitation, exchanges of something of value (e.g.,assets, products, services, currency). The transaction data is immutablystored within the blockchain. That is, the transaction data cannot bechanged.

Before storing in a block, the transaction data is hashed. Hashing is aprocess of transforming the transaction data (provided as string data)into a fixed-length hash value (also provided as string data). It is notpossible to un-hash the hash value to obtain the transaction data.Hashing ensures that even a slight change in the transaction dataresults in a completely different hash value. Further, and as notedabove, the hash value is of fixed length. That is, no matter the size ofthe transaction data the length of the hash value is fixed. Hashingincludes processing the transaction data through a hash function togenerate the hash value. An example of a hash function includes, withoutlimitation, the secure hash algorithm (SHA)-256, which outputs 256-bithash values.

Transaction data of multiple transactions are hashed and stored in ablock. For example, hash values of two transactions are provided, andare themselves hashed to provide another hash. This process is repeateduntil, for all transactions to be stored in a block, a single hash valueis provided. This hash value is referred to as a Merkle root hash, andis stored in a header of the block. A change in any of the transactionswill result in change in its hash value, and ultimately, a change in theMerkle root hash.

Blocks are added to the blockchain through a consensus protocol.Multiple nodes within the blockchain network participate in theconsensus protocol, and perform work to have a block added to theblockchain. Such nodes are referred to as consensus nodes. PBFT,introduced above, is used as a non-limiting example of a consensusprotocol. The consensus nodes execute the consensus protocol to addtransactions to the blockchain, and update the overall state of theblockchain network.

In further detail, the consensus node generates a block header, hashesall of the transactions in the block, and combines the hash value inpairs to generate further hash values until a single hash value isprovided for all transactions in the block (the Merkle root hash). Thishash is added to the block header. The consensus node also determinesthe hash value of the most recent block in the blockchain (i.e., thelast block added to the blockchain). The consensus node also adds anonce value, and a timestamp to the block header.

In general, PBFT provides a practical Byzantine state machinereplication that tolerates Byzantine faults (e.g., malfunctioning nodes,malicious nodes). This is achieved in PBFT by assuming that faults willoccur (e.g., assuming the existence of independent node failures, and/ormanipulated messages sent by consensus nodes). In PBFT, the consensusnodes are provided in a sequence that includes a primary consensus node,and backup consensus nodes. The primary consensus node is periodicallychanged. Transactions are added to the blockchain by all consensus nodeswithin the blockchain network reaching an agreement as to the worldstate of the blockchain network. In this process, messages aretransmitted between consensus nodes, and each of the consensus nodesproves that a message is received from a specified peer node, andverifies that the message was not modified during transmission.

In PBFT, the consensus protocol is provided in multiple phases with allconsensus nodes beginning in the same state. To begin, a client sends arequest to the primary consensus node to invoke a service operation(e.g., execute a transaction within the blockchain network). In responseto receiving the request, the primary consensus node multicasts therequest to the backup consensus nodes. The backup consensus nodesexecute the request, and each sends a reply to the client. The clientwaits until a threshold number of replies are received. In someexamples, the client waits for f+1 replies to be received, where f isthe maximum number of faulty consensus nodes that can be toleratedwithin the blockchain network. The final result is that a sufficientnumber of consensus nodes come to an agreement on the order of therecord that is to be added to the blockchain, and the record is eitheraccepted, or rejected.

In some blockchain networks, cryptography is implemented to maintainprivacy of transactions. For example, if two nodes want to keep atransaction private, such that other nodes in the blockchain networkcannot discern details of the transaction, the nodes can encrypt thetransaction data. An example of cryptography includes, withoutlimitation, symmetric encryption, and asymmetric encryption. Symmetricencryption refers to an encryption process that uses a single key forboth encryption (generating ciphertext from plaintext), and decryption(generating plaintext from ciphertext). In symmetric encryption, thesame key is available to multiple nodes, so each node can en-/de-crypttransaction data.

Asymmetric encryption uses keys pairs that each include a private key,and a public key, the private key being known only to a respective node,and the public key being known to any or all other nodes in theblockchain network. A node can use the public key of another node toencrypt data, and the encrypted data can be decrypted using other node'sprivate key. For example, and referring again to FIG. 2, Participant Acan use Participant B's public key to encrypt data, and send theencrypted data to Participant B. Participant B can use its private keyto decrypt the encrypted data (ciphertext) and extract the original data(plaintext). Messages encrypted with a node's public key can only bedecrypted using the node's private key.

Asymmetric encryption is used to provide digital signatures, whichenables participants in a transaction to confirm other participants inthe transaction, as well as the validity of the transaction. Forexample, a node can digitally sign a message, and another node canconfirm that the message was sent by the node based on the digitalsignature of Participant A. Digital signatures can also be used toensure that messages are not tampered with in transit. For example, andagain referencing FIG. 2, Participant A is to send a message toParticipant B. Participant A generates a hash of the message, and then,using its private key, encrypts the hash to provide a digital signatureas the encrypted hash. Participant A appends the digital signature tothe message, and sends the message with digital signature to ParticipantB. Participant B decrypts the digital signature using the public key ofParticipant A, and extracts the hash. Participant B hashes the messageand compares the hashes. If the hashes are same, Participant B canconfirm that the message was indeed from Participant A, and was nottampered with.

In some embodiments, nodes of the blockchain network, and/or nodes thatcommunicate with the blockchain network can operate using trustedexecution environments (TEEs). At a high-level, a TEE is a trustedenvironment within hardware (one or more processors, memory) that isisolated from the hardware's operating environment (e.g., operatingsystem (OS), basic input/output system (BIOS)). In further detail, a TEEis a separate, secure area of a processor that ensures theconfidentiality, and integrity of code executing, and data loaded withinthe main processor. Within a processor, the TEE runs in parallel withthe OS. At least portions of so-called trusted applications (TAs)execute within the TEE, and have access to the processor and memory.Through the TEE, the TAs are protected from other applications runningin the main OS. Further, the TEE cryptographically isolates TAs from oneanother inside the TEE.

An example of a TEE includes Software Guard Extensions (SGX) provided byIntel Corporation of Santa Clara, Calif., United States. Although SGX isdiscussed herein by way of example, it is contemplated that embodimentsof this specification can be realized using any appropriate TEE.

SGX provides a hardware-based TEE. In SGX, the trusted hardware is thedie of the central processing until (CPU), and a portion of physicalmemory is isolated to protect select code and data. The isolatedportions of memory are referred to as enclaves. More particularly, anenclave is provided as an enclave page cache (EPC) in memory and ismapped to an application address space. The memory (e.g., DRAM) includesa preserved random memory (PRM) for SGX. The PRM is a continuous memoryspace in the lowest BIOS level and cannot be accessed by any software.Each EPC is a memory set (e.g., 4 KB) that is allocated by an OS to loadapplication data and code in the PRM. EPC metadata (EPCM) is the entryaddress for respective EPCs and ensures that each EPC can only be sharedby one enclave. That is, a single enclave can use multiple EPCs, whilean EPC is dedicated to a single enclave.

During execution of a TA, the processor operates in a so-called enclavemode when accessing data stored in an enclave. Operation in the enclavemode enforces an extra hardware check to each memory access. In SGX, aTA is compiled to a trusted portion, and an untrusted portion. Thetrusted portion is inaccessible by, for example, OS, BIOS, privilegedsystem code, virtual machine manager (VMM), system management mode(SMM), and the like. In operation, the TA runs and creates an enclavewithin the PRM of the memory. A trusted function executed by the trustedportion within the enclave is called by the untrusted portion, and codeexecuting within the enclave sees the data as plaintext data(unencrypted), and external access to the data is denied. The trustedportion provides an encrypted response to the call, and the TA continuesto execute.

An attestation process can be performed to verify that expected code(e.g., the trusted portion of the TA) is securely executing within theSGX-provided TEE. In general, the attestation process includes a TAreceiving an attestation request from a challenger (e.g., another nodein the blockchain network, a key management system (KMS) of theblockchain network). In response, the TA requests that its enclaveproduce a remote-attestation, also referred to as a quote. Producing theremote-attestation includes a local-attestation being sent from theenclave to a so-called quoting enclave, which verifies thelocal-attestation, and converts the local-attestation into theremote-attestation by signing the local-attestation using an asymmetricattestation key. The remote-attestation (quote) is provided to thechallenger (e.g., KMS of the blockchain network).

The challenger uses an attestation verification service to verify theremote-attestation. For SGX, Intel provides the Intel AttestationService (IAS), which receives the remote-attestation from thechallenger, and verifies the remote-attestation. More particularly, theIAS processes the remote-attestation, and provides a report (e.g.,attestation verification report (AVR)), which indicates whether theremote-attestation is verified. If not verified, an error can beindicated. If verified (the expected code is securely executing in theTEE), the challenger can start, or continue interactions with the TA.For example, in response to the verification, the KMS (as challenger)can issue asymmetric encryption keys (e.g., a public-key and private-keypair) to the node executing the TEE (e.g., through a key exchangeprocess, such as elliptical curve Diffie-Hellman (ECDH)) to enable thenode to securely communicate with other nodes, and/or clients.Additional details of the TEE technology is described in, e.g., PCTapplication PCT/CN2019/081180, filed on Apr. 3, 2019, the contents ofwhich are incorporated by reference.

The blockchain and TEE technologies described above can be used togenerate highly reliable records related to online transactions. Anonline transaction typically involves multiple steps. Instead ofgenerating a verified record of the end result of a transaction, such asgenerating a hash value of data generated at the end of the transaction,the novel systems described in this specification use data generatedduring multiple events that occurred throughout the multiple steps ofthe transaction to generate a record that can be used to verify thetransaction. A verified record of the data derived from eventsassociated with the multiple steps of a transaction is much morereliable than a verified record based on just the end result of thetransaction. In some embodiments, for each piece of data that needs tobe verified, not only is the piece of data itself verified, the processof generating the piece of data is also verified. The process ofgenerating the piece of data may involve multiple steps, and each stepof the process is verified. This ensures that the final piece of data ishighly reliable because the probability that every step of the processhas been fraudulently modified is very low. In some embodiments, a toolis provided for gathering evidence in the form of digital data. For eachpiece of evidence that needs to be verified, not only is the evidenceitself verified, the process of collecting or generating the evidence isalso verified. The process of collecting or generating the evidence mayinvolve multiple steps, and each step of the process is verified. Thisensures that the evidence collected or generated at the end of theprocess is highly reliable because the probability of someonefraudulently modifying the data in every step of the process is verylow.

Referring to FIG. 3, this specification describes technologies forenabling a blockchain-based trusted platform 300 (which can be a trustedonline platform) that enhances trust among users and provides variouslegal service or process tools to allow users to conduct legalproceedings, or transactions associated with legal services, in anefficient manner. The legal service tools provided by theblockchain-based trusted platform 300 include, e.g., a blockchain-basedservice of process tool 302, a blockchain-based dispute resolution tool304, a blockchain-based legal documentation tool 306, and ablockchain-based judgement execution tool 308. The service of processtool 302 allows a plaintiff to serve notice (e.g., serve summons orother related documents) to a defendant digitally while complying withthe legal requirements for service of process. The dispute resolutiontool 304 allows two or more parties in dispute to find one or morepotential (or candidate) solutions to the dispute from multiple disputeresolution providers (e.g., dispute mediators) in a convenient manner.The legal documentation tool 306 allows users to fill out and submitlegal documents digitally in ways that comply with relevant legalrequirements. The judgement execution tool 308 allows a plaintiff toexecute a court ordered judgement, such as serving a bank levy courtorder to a defendant's bank digitally, in a way that complies withrelevant legal requirements. The tools 302, 304, 306, and 308 areprovided in a trusted application layer 322 of the trusted platform 300.The trusted platform 300 also includes a trusted service layer 324 thatincludes, e.g., a trusted timing module 310, a trusted identity module312, and a trusted computing module 314 to support the operations of thevarious legal service tools in the trusted application layer 322.

Conducting legal transactions online in a digital manner has theadvantage that the transactions can be performed quickly and efficientlyin part because there is no need to fill out legal paper documents andsend the legal paper documents by hand delivery or postal mail. However,the ephemeral nature of digital data also makes it difficult toauthenticate or verify the transactions that have been completeddigitally online in a manner that satisfies court evidentiary rules.Unlike a paper document in which modifying contents printed on the papermedium often leaves evidence of the modification, such as alterations tothe paper fibers or ink molecules, modifying a digital document oftendoes not leave any trace of modification. Furthermore, digital documentscan be corrupted due to hardware errors, such as failure of storagesystems such as magnetic disk drives, solid state drives, and/or memorydevices. As a result, the contents of a digital document, the identityof the user associated with the digital document, and the timingassociated with the digital document may be questionable.

There are techniques for authenticating a digital document exchangedbetween two parties, such as computing the hash value of the digitaldocument and sharing the hash value with the two parties. There aretechniques for authenticating the identities of parties associated witha digital document, such as using verified digital signatures. However,while such techniques are useful in authenticating the contents ofindividual documents and/or the identities of parties associated withthe individual documents in limited situations, legal disputes oftenarise in situations in which no such agreed-upon hash values or verifieddigital signatures are available.

For example, party A (e.g., an author of a copyrighted material) accusesparty B (e.g., an online publisher) of hosting web pages having contentsthat infringe the copyright of party A. Party A files a complaint with acourt and submits to the court a copy of the web pages that allegedlyinclude the copyright-infringing contents. Party B denies ever hostingsuch copyright-infringing material on the web pages and alleges thatParty A modified the contents or the URL of the web pages used asevidence in support of the false accusation. Party A alleges that PartyB modified the web pages published on the web site and removed thecopyright-infringing contents after learning of the lawsuit. Party Balleges that the person who filed the complaint is not party A, butsomeone else who is not eligible to file the complaint. In this case,both the evidence and the identity of the party are in question. Asanother example, party C (e.g., a seller) alleges that party D (e.g., abuyer) placed an order for a product on an online flea market and neverpaid for the product. Party C files a complaint with the court andsubmits to the court a copy of the digital order. Party D denies everplacing the order and alleges that the order was placed by someone elsewho pretended to be party D. As yet another example, party E and party Fnegotiate an agreement, make several modifications to the earlier draftsof the agreement, and eventually sign a final version of the agreement.The entire process was completed online without exchanging any paperdocument. Later, party E files a complaint with the court alleging thatparty F did not comply with certain terms of the agreement. Party Fstates that it complied with all the terms of the agreement, andcounterclaims that party E fraudulently modified the agreement after ithas been signed digitally. Party E and party F produce two differentversions of the final digitally signed agreement. Further to theexample, Party F countersigned the agreement, but sent to a wrong e-mailaddress until discovered several days later before delivering to thecorrect e-mail address of Party E. Party E then relied on the deliverydate to perform the agreement while Party F relied on the date thecontract was countersigned. When the court receives the complaintsmentioned above, it may be difficult for the court to properlyadjudicate the disputes because of the difficulty verifying theauthenticity of the evidence provided by the parties.

In some examples, the parties can hire lawyers to gather evidence andfile affidavits with the court attesting the authenticity of theevidence. However, hiring and coordinating with lawyers can be expensiveand time consuming. In some situations, events that are in dispute havealready occurred, the relevant digital documents have already beenaltered, and even the lawyers have difficulty gathering relevantevidence.

The blockchain-based trusted platform 300 solves the problems describedabove by providing a suite of legal service application programs thatutilize the functions of the trusted timing module 310, the trustedidentity module 312, and the trusted computing module 314 toauthenticate documents and/or identities of users in a manner thatcomplies (or is more compliant compared with previous systems) withrelevant evidentiary rules.

Some court systems and government agencies allow citizens to file legalcomplaints online. For example, the Internet Court in Hangzhou, China,accepts complaints and filings electronically and tries cases vialivestreaming. The British Columbia Civil Resolution Tribunal is anonline tribunal in Canada that resolves certain types of disputesonline. For example, the trusted platform 300 can connect with the courtsystems and provide an integrated user interface so that users can filecomplaints and submit evidence to the court systems in a convenientmanner.

In some embodiments, a novel feature of the blockchain-based trustedplatform 300 is that the platform provides trusted time, trustedidentity, and trusted computing to enable application programs thatprovide legal services to preserve verified records of information(e.g., who, what, and when) about events that occur during each ofmultiple steps or critical time points of the services in ways thatcomply (or are more compliant compared to previous systems) withevidentiary rules. These records can be added to a blockchain throughconsensus of blockchain nodes associated with legal, law enforcement, ordispute resolution authorities. Once added, the records become immutableand can be trusted by the court or the parties as evidence for thecorresponding legal services or processes.

For example, there are tools that provide hash and digital signaturefunctions to allow a user to digitally sign data so that other users canverify that the data has not been changed since it was signed, and toverify the identity of the user who signed the data. However, there isstill a possibility that the digitally signed data contain errors, e.g.,the data was corrupted or tampered with unbeknownst to the signer beforethe data was signed, or that the original digitally signed data wasintercepted by a hacker during transmission and replaced with forgeddigitally signed data. Based on the digitally signed data alone, it maybe difficult to prove or disprove the authenticity and accuracy of thedata. Thus, it may be difficult to use the digitally signed data inlegal proceedings without further proof, such as an affidavit from anotary or a licensed attorney attesting to the authenticity and accuracyof the data. A technical problem to be solved is how to increase theconfidence level of data produced by online application programs thatprovide legal services.

The blockchain-based trusted platform 300 enhances the trustworthinessof data produced by an application program that provides a legal serviceover the network and reduces the probability of forgery or tampering bycapturing snapshots of each of multiple steps (or at several criticaltime points) in the process of providing the legal service, eachsnapshot including information provided by the trusted timing module 310and/or the trusted identity module 312, and storing the snapshots in ablockchain using the trusted computing module 314 to process theblockchain data. The snapshots can include, e.g., information such aswho, when, and what associated with the events that occur during thecorresponding steps or time points. The probability of forgery ortampering in every one of the multiple steps (or time points) becomesmuch smaller than the probability of forgery or tampering in a singlestep (or time point). The trusted time module 310 provides trusted orverified time stamps, the trusted identity module 312 provides trustedor verified identity information, and the trusted computing module 314ensures trustworthiness of the data recorded in relevant blockchains.

In some embodiments, functions of the modules 310, 312, 314 can beinvoked by one or more blockchain-based application programs or smartcontract executed in a TEE. The TEE is hosted by one or more dataprocessors isolated from the one or more data processors' operatingsystem and is configured to provide enhanced confidentiality andintegrity of code executing and data loading within the one or more dataprocessors. In some examples, the application programs or smart contractcan invoke the functions of the modules through an application programinterface (API).

The blockchain-based trusted platform 300 produces a technical effect inwhich data related to the legal service provided by the legal serviceapplication program supported by the blockchain-based trusted platform300 have a higher level of trustworthiness (compared with previoussystems). The data verifying the identities of parties related to thelegal service have a higher level of trustworthiness. The data verifyingthe actions performed by the parties have a higher level oftrustworthiness. The data verifying the timing of events that occurredduring the provision of the legal service have a higher level oftrustworthiness. The data verifying the documents that were shown to,provided to, or edited by parties related to the legal service at eachof multiple steps or time points have a higher level of trustworthiness.A highly reliable record of a history of transactions that occurredduring the provision of the legal service, including a history ofmodifications to documents and responses from various parties, can bepreserved.

In some embodiments, the trusted service layer 324 can includeadditional modules, such as a trusted positioning module, that providesa verified position indicating where a transaction occurred. Forexample, the trusted positioning module can be used to prove that aninfringement action occurred in a certain geographical region, and thata complaint can be filed in the court that has jurisdiction. Forexample, the trusted positioning module can generate verified positioninformation based on data provided by a verified GPS receiver connectedto a client terminal 404 (FIG. 4).

The trusted platform 300 includes additional application programs, e.g.,a first application program 316, a second application program 318, . . ., and an N-th application program 320 that utilize the functions of thetrusted timing module 310, the trusted identity module 312, and thetrusted computing module 314. The following describes an example inwhich the first application program 316 provides an “Internet evidencegathering web browser” 424 (FIG. 4) that can be used to collect evidenceon the Internet.

Referring to FIG. 4, in some embodiments, the trusted platform 300 canbe accessed through a network 400, such as the Internet. A user 402accesses the trusted platform 300 using a client terminal 404, which canbe, e.g., a mobile phone, a personal computer, or any computing devicethat can connect to the network 400. In some examples, the trustedplatform 300 provides limited functions to users who have not registeredwith the platform 300. The platform 300 provides more (e.g., full)functions of the tools 302, 304, 306, 308, the application programs 316,318, 320, and the modules 310, 312, 314 to users who have registeredwith the platform 300.

Upon registration with the platform 300, the user has a user identifier(ID) that is used to identify the user 402 when the user 402 uses thetools and services of the platform 300. Each registered user has anaccount associated with the platform 300 and can access the functions ofthe platform 300 after logging into the account. In some examples, theuser can register with the platform 300 by providing personalinformation, such as a phone number and an e-mail address of the user.In some examples, the user can register with the platform 300 byproviding biometric information, such as one or more fingerprints, oneor more voiceprints, or iris information through a fingerprint sensor, amicrophone, or an iris scanner communicably coupled to the modules 310,312, 314. As the user accesses functions of the trusted platform 300,the user may provide additional information to the trusted platform 300,and the trusted platform 300 associates the additional information withthe user account.

For example, the user 402 may provide a mobile phone number so that theuser 402 can receive messages from the trusted platform 300 on a mobilephone. The user 402 may provide payment account information so that theuser 402 can pay for services on the trusted platform 300. For example,the user account may include one or more of the following informationthat can be used to verify the identity of the user 402: (i) a mobilephone number, (ii) a credit card number, (iii) a user ID associated withan online payment system, (iv) a user ID associated with an onlineshopping account, (v) a user ID associated with a music streaming ordownloading account, (vi) a user IDS associated with a movie streamingor downloading account, (vii) a user ID associated with a messaging orchat account, (viii) a user ID associated with an online bankingaccount, (ix) a user ID associated with a ride hailing service, (x) auser ID associated with an online food ordering service, (xi) a socialsecurity number, (xii) a driver's license number, (xiii) a passportnumber, (xiv) a user ID associated with an online gaming service, (xv)an ID issued by a government entity, (xvi) one or more fingerprints,(xvii) one or more voiceprints, or (xviii) iris information.

In the example of FIG. 4, the user 402 accesses the Internet evidencecollecting web browser 422 to search for and view web pages on theInternet 400. A client component (not shown in the figure) of the webbrowser executes at the client terminal 404 and provides a userinterface for displaying the web pages to the user 402 and receiving theuser's instructions for handling the web pages, such as clicks forcontrolling navigation among the web pages. Similarly, in someembodiments, when the user 402 accesses the tool 302, 304, 306, or 308,or the application program 318 or 320, a corresponding client componentexecutes at the user terminal 404 and provides a corresponding userinterface for interacting with the user 402.

For example, the user 402 uses the web browser 422 to access web pages406 (including, e.g., web pages 406 a and 406 b) hosted on a web server408 of a publisher. The user 402 may initially provide the URL of thehome page of the publisher, and click on web links to browse the webpages hosed on the web server 408. In some embodiments, when the user402 uses the Internet evidence collecting web browser 424 to browse webpages, the web browser 424 invokes the trusted identity module 312 toverify the identity of the user 402. For example, the trusted identitymodule 312 can use any number of information associated with the useraccount to verify the identity of the user 402. For example, the trustedidentity module 312 can use one or more of the following information toverify the identity of the user 402: (i) a mobile phone number, (ii) acredit card number, (iii) a user ID associated with an online paymentsystem, (iv) a user ID associated with an online shopping account, (v) auser ID associated with a music streaming or downloading account, (vi) auser ID associated with a movie streaming or downloading account, (vii)a user ID associated with a messaging or chat account, (viii) a user IDassociated with an online banking account, (ix) a user ID associatedwith a ride hailing service, (x) a user ID associated with an onlinefood ordering service, (xi) a social security number, (xii) a driver'slicense number, (xiii) a passport number, (xiv) a user ID associatedwith an online gaming service, (xv) an ID issued by a government entity,(xvi) one or more fingerprints, (xvii) one or more voiceprints, or(xviii) iris information.

For example, each time a pre-specified type of event occurs inconnection with the use of the web browser 424 by the user 402, the webbrowser 424 invokes the trusted timing module 310 to obtain a verifiedtime stamp regarding when the event occurred. The pre-specified type ofevents can include, e.g., receiving an input from the user 402,providing an output to the user 402, and performing a pre-specified typeof action or computation. Receiving an input from the user 402 caninclude, e.g., receiving a URL of a web page, receiving a click commandor a selection command from the user 402, receiving an edit command,such as a copy command, from the user 402, or receiving a file command,such as a save command, from the user 402. Providing an output to theuser 402 can include, e.g., displaying the contents of a web page to theuser 402, playing an audio file to the user 402, or playing a video fileto the user 402.

Thus, each time an event occurs, in which the user 402 performs apre-specified type of action, such as providing a URL to the web browser424, clicking on a web link on the web page 406, copying text or imagesfrom the web page 406, or downloading content from the web page 406, theweb browser 424 performs the action requested by the user 402 and alsoinvokes the trusted timing module 310 to obtain a verified time stampindicating a time when the action was performed or when the eventoccurred. The web browser 424 invokes the trusted computing module 314to generate a snapshot of the event, in which the snapshot can be in theformat of a record that includes the identity of the user 402, adescription of the event (such as a description of the action that wasperformed), a verified time stamp indicating when the event occurred(such as when the action was performed), and information (e.g., URL)about the web page associated with the action. The trusted computingmodule 314 generates a hash value of the record, and adds a block thatincludes the record and the hash value to a blockchain 410 that storesrecords associated with the user 402.

For example, the following events may be associated with the browsingactivities of the user 402.

-   -   a. Event 1: The user 402 provides a URL of a first web page 406        a of the publisher to the web browser 424.    -   b. Event 2: The web browser 424 retrieves the first web page 406        a from the web server 408 and shows the web page 406 a to the        user 402.    -   c. Event 3: The user 402 clicks on a link that points to a        second web page 406 b.    -   d. Event 4: The web browser 424 retrieves the second web page        406 b from the web server 408 and shows the web page 406 b to        the user 402.    -   e. Event 5: The user 402 saves a photo 422 on the second web        page 406 b and writes a note: “Copyrighted photo found on        publisher X's web page having URL xxx.”    -   f. Event 6: The user 402 exits the web browser 424.        Upon the occurrence of each event, the web browser 424 invokes        the trusted timing module 310 to obtain a verified time stamp        indicating the time that the event occurred. The web browser 424        invokes the trusted computing module 314 to update the        blockchain 410 to add a record having information about the        event. In this example, a block 412 a stores the record having        information about event 1, block 412 b stores the record having        information about event 2, block 412 c stores the record having        information about event 3, and so forth.

The trusted platform 300 is associated with one of the nodes 414 of ablockchain network 416 in which the blockchain 410 is replicated acrossthe blockchain network 416. For example, one of the nodes 414 can beassociated with a computer server 418 of a court that maintains aversion of the blockchain 410. If the user 402 files a complaint withthe court alleging copyright infringement by the publisher of the webpages 406, a court staff can access the records in the blockchain 410maintained at the court computer server 418 to retrieve informationabout the events 1 to 6 described above. The court staff can determinethat the user 402 viewed the second web page 406 b and saved the photo422 from the second web page 406 b with a note: “Copyrighted photo foundon publisher X's web page having URL xxx.” Because the records in theblockchain 410 has a high level of trustworthiness, the court acceptsthe information provided by the records in the blockchain 410 asevidence submitted by the user 402.

Referring to FIG. 5, in some embodiments, the trusted timing modulegenerates verified time stamps based on the coordinated universal time(UTC) 500 that is distributed by a national standard institution, ortiming information generated by a global positioning system (GPS)receiver 502 that derives the timing information from positioningsystems such as the BeiDou Navigation Satellite System maintained byChina, the Global Positioning System maintained by the United States,the Galileo global navigation satellite system maintained by theEuropean Union, the Global Orbiting Navigation Satellite System(GLONASS) maintained by Russia, and/or the Quasi-Zenith SatelliteSystem) maintained by Japan.

In some embodiments, the trusted platform 300 can be accessed byworldwide users located in many countries. Different countries may havedifferent requirements or preferences regarding what timing informationis acceptable as evidence in legal proceedings. For example, a court inBeijing may accept timing information derived from UTC time provided bythe National Time Service Center, or timing information derived from theBeiDou Navigation Satellite System. A court in New York may accepttiming information derived from UTC time provided by the NationalInstitute of Standard and Technology or timing information derived fromthe U.S. Global Positioning System. The trusted platform 300 isconfigured to determine the legal jurisdiction in which a user resides,and use the timing reference acceptable to the corresponding courtsystem when generating time stamps for the activities associated withthe user. In some examples, the trusted platform 300 allows the user toselect which timing reference to use.

Referring to FIG. 6, in some embodiments, the trusted identity module312 maintains a user account database 600 that includes informationabout registered users provided by the users themselves. The trustedidentity module 312 also accesses other databases to verify the accountinformation provided by the users. For example, the trusted identitymodule 312 can access a government ID database 602 to verify theaccuracy of the government ID provided by the user. For example, if thetrusted identity module 312 determines that the government ID providedby the user matches the name or phone number of another user listed inthe government ID database 602, the trusted identity module 312 maygenerate an alert message indicating the possibility of fraudulentidentity. The tool (e.g., 302, 304, 306, or 308) or application program(e.g., 316, 318, or 320) upon receiving the alert message from thetrusted identity module 312 may request additional information from theuser in order to verify the identity of the user.

In some embodiments, the trusted platform 300 may provide online bankingservices and maintain a database 604 of the accounts of the users whoaccess the online banking services. The trusted platform 300 can provideonline payment services, such as Alipay, that allow users to digitallypay for services provided on the trusted platform 300. The trustedplatform 300 can maintain a database 606 of the accounts of the userswho use the online payment services provided on the trusted platform300. The trusted platform 300 can provide social media services thatallow users to connect with family members, relatives, friends,colleagues, and/or fans. The trusted platform 300 can maintain adatabase 608 of the accounts of the users who use the social mediaservices provided on the trusted platform 300. The trusted platform 300can provide communication services, such as instant messaging or chatservices, that allow users to communicate with other people. The trustedplatform 300 can maintain a database 610 of the accounts of the userswho use the communication services provided on the trusted platform 300.The trusted platform 300 can have contracts with mobile phone companiesin which the mobile phone companies assist in verifying whether a mobilephone number and other account information provided by a user to thetrusted platform 300 during registration match corresponding informationregistered with the mobile phone companies.

The trusted platform 300 can provide online shopping services that allowusers to shop for products online. The trusted platform 300 can maintaina database 612 of the accounts of the users who use the online shoppingservices provided on the trusted platform 300. The trusted platform 300can provide online shopping services that allow users to shop forproducts online. The trusted platform 300 can maintain a database 612 ofthe accounts of the users who use the online shopping services providedon the trusted platform 300. The trusted platform 300 can provide onlineentertainment services to allow users to listen to music or watch moviesby downloading or streaming the music or movies. The trusted platform300 can maintain a database 614 of the accounts of the users who use theonline entertainment services provided on the trusted platform 300. Thetrusted platform 300 can maintain a biometric database 616 that storesbiometric information, such as one or more fingerprints, one or morevoiceprints, or iris information, provided by the users duringregistration.

In some embodiments, the various databases 600, 602, 604, 606, 608, 610,612, 614, 616 can be maintained independently of one another. Forexample, a user can modify the information in the online banking accountwithout modifying the information in the online shopping account. A usermay update information in different accounts at different periods oftime. The same user can use different user names or aliases fordifferent services. Multiple users can share the same account, e.g.,family members may share the same movie streaming account. The same usercan open multiple accounts with a service, e.g., a user can havemultiple mobile phone numbers, e-mail addresses, and/or messaging IDs.Thus, based on the information of a single database, it may not besufficient to accurately verify the identity of a user. However, bycombining information from multiple databases, the identity of the usercan be more reliably verified.

A feature of the trusted platform 300 is that the trusted identitymodule 312 attempts to verify the identity of the user using multipledatabases, thus increasing the trustworthiness of the verified identityinformation provided by the trusted identity module 312. The trustedidentity module 312 can access one or more of the government ID database602, the online banking accounts database 604, the online paymentaccounts database 606, the social media accounts database 608, themobile communication accounts database 610, the online shopping accountsdatabase 612, the online entertainment accounts database 614, and thebiometrics database 616 as part of the process of verifying the identityof the user. For example, if the name and e-mail address provided by theuser during registration do not match those in the online bankingaccounts database 604 and/or the online payment accounts database 606,the trusted identity module 312 may generate an alert message indicatingthe possibility of fraudulent identity, and the trusted platform 300 mayrequest additional information from the user in order to verify theidentity of the user.

In some embodiments, when a tool or application program invokes thetrusted identity module 312 to verify the identity of a user, the toolor application program sends the ID and other information of the user tothe trusted identity module 312, and the trusted identity module 312compares the ID and other information of the user provided by the toolor application program with the user information stored in the useraccounts database 600 and the other databases 602, 604, 606, 608, 610,612, 614, and 616. If the user information provided by the tool orapplication program is consistent with the user information stored inthe databases, the trusted identity module 312 verifies the identity ofthe user. On the other hand, if the user information provided by thetool or application program is inconsistent with the user informationstored in one or more of the databases, the trusted identity module 312generates an alert message indicating that the identity of the usercannot be verified.

In some embodiments, the trusted identity module 312 can generated atrust score along with the verified identity. For example, if a useraccesses one of the tools or application programs on the trustedplatform 300, and the accounts associated with the user have beeninactive for many years, the trusted identity module 312 can generate alow trust score for the identity of the user because the stale data inthe databases may not be entirely accurate. On the other hand, if a useris very active on the trusted platform 300, uses many services providedby the trusted platform 300, and account information in the majority orall the databases associated with the user are consistent with oneanother, the trusted identity module 312 can generate a high trust scorefor the identity of the user because there is a low probability that theaccount information in the majority or all of the databases areconsistently fraudulent.

The following describes an example of using the service of process tool302 to serve notice. Referring to FIG. 7, in some embodiments, a firstuser 708 (which can be, e.g., the plaintiff or an attorney representingthe plaintiff) accesses the trusted platform 300 using a client terminal710, which can be, e.g., a mobile phone, a personal computer, or anycomputing device that can connect to the network 400. In this example,the first user 708 has previously registered with the trusted platform300. After logging into the trusted platform 300, the first user 708 canaccess the service of process tool 302.

In some embodiments, the service of process tool 302 can require usersto open an account and follow an additional registration process toprovide additional personal information in order to verify the identityof the users. For example, the user account associated with the serviceof process tool 302 may include one or more of the following informationthat can be used to verify the identity of the user: (i) a mobile phonenumber, (ii) a credit card number, (iii) a user ID associated with anonline payment system, (iv) a user ID associated with an online shoppingaccount, (v) a user ID associated with a music streaming or downloadingaccount, (vi) a user IDS associated with a movie streaming ordownloading account, (vii) a user ID associated with a messaging or chataccount, (viii) a user ID associated with an online banking account,(ix) a user ID associated with a ride hailing service, (x) a user IDassociated with an online food ordering service, (xi) a social securitynumber, (xii) a driver's license number, (xiii) a passport number, (xiv)a user ID associated with an online gaming service, (xv) an ID issued bya government entity, (xvi) one or more fingerprints, (xvii) one or morevoiceprints, or (xviii) iris information.

Assume that the first user 708 has previously registered with theservice of process tool 300. During the log-in process, the service ofprocess tool 302 can invoke the trusted identity module 312 to verifythe identity of the first user 708. After the trusted identity module312 verifies the identity of the first user 708, the service of processtool 302 can grant access to the first user 708. The first user 708 canaccess the service of process tool 302 to serve court issued documents,such as a summons or subpoena, to another user 712 (second user 712),which can be, e.g., a defendant 714 or an attorney for the defendant. Aclient component (not shown in the figure) of the service of processtool 302 can be executed at the client terminal 710 and provides a userinterface for interacting with the first user 708.

For example, each time a pre-specified type of event occurs inconnection with the use of the service of process tool 302 by the firstuser 708, the service of process tool 302 invokes the trusted timingmodule 310 to obtain a verified time stamp regarding when the eventoccurred. The pre-specified type of events can include, e.g., receivingan input from the first user 708, providing an output to the first user708, transmitting a document to the second user 712, confirming receiptof the document by the second user 712, and performing a pre-specifiedtype of action or computation. Receiving an input from the first user708 can include, e.g., receiving the user ID or other personalinformation associated with the second user 712 who is supposed toreceive notice, and receiving an upload file, such as a court issuedsummons or subpoena, from the first user 708. Providing an output to thefirst user 708 can include, e.g., displaying evidence that the documenthas been served on the second user 712, or a message indicating that thesecond user 712 cannot be reached.

As described above, the service of process tool 302 can invoke servicesfrom the trusted service layer 324. In some embodiments, each time anevent occurs, such as a user 708 complainant enters an identityinformation through the service of process tool 302, the service ofprocess tool 302 can invoke the trusted timing module 310 to record averified time stamp indicating a time when the triggering eventoccurred. In some embodiments, the service of process tool 302 caninvoke the trusted computing module 314 to generate a snapshot of theevent. For example, the snapshot can include the identity of the user708 or 712, a description of the event (e.g., a notice of a legal actionsent through e-mail), a verified time stamp indicating a time of thetriggering event, and supplemental information (e.g., document format),etc. In some embodiments, the trusted computing module 314 can furthergenerate hash values corresponding to the records generated by thetrusted modules 310, 312, 314. The hash values can then be recorded to ablockchain 700 such that they can be used by users of the trustedplatform 302 to verify authenticity of the records.

For example, the following events may be associated with the service ofprocess activities of the first user 708.

-   -   g. Event 1: The first user 708 provides the user ID, address,        and phone number of the second user 712 to the service of        process tool 302.    -   h. Event 2: The first user 708 uploads the document to be        served, such as the summons or subpoena, to the service of        process tool 302.    -   i. Event 3: The service of process tool 302 determines all the        communication methods that can be used to send the document to        the second user 712. For example, the communication methods can        include sending the document to one or more e-mail accounts,        instant messaging accounts, or mobile phone messaging accounts        of the second user 712.    -   j. Event 4: The service of process tool 302 sends the document        to the second user 712 using all available communication methods        supported by the service of process tool 302.    -   k. Event 5: The service of process tool 302 receives        confirmation that the document has been sent to the second user        712. For example, a mobile phone messaging system may indicate        that the second user 712 is online and has received the        document.    -   l. Event 6: Alternatively, the service of process tool 302 may        not receive any confirmation that the document has been received        by the second user 712, and determines that the second user 712        is off-line and cannot be reached.    -   m. Event 7: The service of process tool 302 notifies the first        user 708 that the document has been served on the second user        712, or that the second user 712 cannot be reached.        Upon the occurrence of each event, the service of process tool        302 can invoke the trusted timing module 310 to obtain a        verified time stamp indicating the time that the event occurred.        The service of process tool 302 invokes the trusted computing        module 314 to update the blockchain 700 to add a record having        information about the event. In this example, a block 702 a        stores the record having information about event 1, a block 702        b stores the record having information about event 2, a block        702 c stores the record having information about event 3, and so        forth. In some embodiments, multiple events can be combined and        stored in a single block in the blockchain 700.

The service of process tool 302 is associated with one of the nodes 706of a blockchain network 704 in which the blockchain 700 is replicatedacross the blockchain network 704. For example, one of the nodes 706 canbe associated with a computer server 418 of a court that maintains aversion of the blockchain 700. If the first user 708 notifies the courtthat the summons or subpoena has been served on the second user 712, acourt staff can access the records in the blockchain 700 maintained atthe court computer server 418 to retrieve information about the events 1to 7 described above. The court staff can determine that the first user708 has served the summons or the subpoena to the second user 712.Because the records in the blockchain 700 has a high level oftrustworthiness, the court accepts the information provided by therecords in the blockchain 700 as evidence that the second user 712 hasbeen properly served notice.

A feature of the service of process tool 302 is that it can determinemultiple communication methods that can be used to send the document tothe second user 712. For example, when a user registers with the trustedplatform 300, the trusted platform 300 can request the user to providetwo or more contact methods (e.g., one or more e-mail addresses, one ormore phone numbers (e.g., home, office, and mobile phone numbers),and/or one or more messaging app contact information) in order to verifythe identity of the user. The service of process tool 302 can use thecontact methods provided by the second user 712 to the trusted platform300 during registration in order to serve legal notice to the seconduser 712. In addition, when the second user 712 uses one or moreservices provided on the trusted platform 300, the second user 712 mayprovide updated contact information to those services from time to time,so the trusted platform 300 can have updated contact information of thesecond user 712.

In some embodiments, when the service of process tool 302 attempts todeliver a legal notice to the second user 712, the service of processtool 302 can first detect whether the second user 712 is currentlylogged into the trusted platform 300 and using one or more servicesprovided by the trusted platform 300, and determine the most efficientmethod of sending the legal notice to the second user 712. For example,if the trusted platform 300 detects that the second user 712 iscurrently using a messaging service provided on the trusted platform300, the service of process tool 302 can send the court ordered documentto the second user 712 using the messaging service. In some embodiments,the messaging service can have a built-in read receipt functionindicating that a message has been read, and can send a read receiptback to the service of process tool 302. In some embodiments, theservice of process tool 302 requests the second user 712 to manuallyacknowledge receipt and confirm identity. The second user 712 canconfirm identity by providing one or more identifying information, andthe service of process tool 302 invokes the trusted identity module 312to verify the identity of the second user 712 to ensure that the personwho received the court ordered document is indeed the intendedrecipient. The service of process tool 302 further invokes the trustedtiming module 310 to generate a time stamp indicating the time of theread receipt from the messaging app or the time that the second user 712acknowledge receipt.

It is advantageous for the first user 708 to use the service of processtool 302 because the tool 302 may be able to communicate with the seconduser 712 using a communication method that may not be known to the firstuser 708. For example, the first user 708 may only have a postal mailingaddress of the second user 712, in which the mailing address may or maynot be up-to-date. By using the service of process tool 302, the firstuser 708 can more efficiently serve notice to the second user 712 usingthe most recent contact information of the second user 712 available tothe trusted platform 300. In some embodiments, when a user registerswith the trusted platform 300, the trusted platform 300 obtains consentfrom the user agreeing that the trusted platform 300 can serve legalnotice using the communication methods provided by the user duringregistration.

The following describes another embodiment of the service of processtool. FIG. 8 is a diagram illustrating an example of a system 800 inaccordance with embodiments of this specification. The system 800implements a service of process based on a blockchain network. Ingeneral, a service of process is the procedure by which a party to alawsuit gives an appropriate notice of initial legal action to anotherparty (such as a defendant), court, or administrative body in an effortto exercise jurisdiction over that person so as to enable that person torespond to the proceeding before the court, body, or other tribunal. Forexample, system 800 can be implemented to enable delivering a legalnotice (e.g., notice 820) from a first party (e.g., user 802 a operatingon client terminal 804 a) to a second party (e.g., user 802 b operatingon client terminal 804 b).

As an example, the system 800 includes client terminals 804 a and 804 b(used by users 802 a and 802 b, respectively), a blockchain-basedtrusted platform 300, and a blockchain network 816. As shown, theblockchain-based trusted platform 300 includes a service of process tool302, application programming interfaces (API) 810, 812, and 814, atrusted timing module 310, a trusted identity module 312, and a trustedcomputing module 314. Note that the blockchain-based trusted platform300 is shown to include the service of process tool 302 for illustrativepurposes only. The blockchain-based trusted platform 300 can include anysuitable number of tools, such as a dispute resolution tool (e.g.,dispute resolution tool 304 of FIG. 3), a legal documentation tool(e.g., legal documentation tool 306) and a judgement execution tool(e.g., judgement execution tool 308), etc. In some embodiments, thetrusted platform 300 is associated with one of the nodes 818 of theblockchain network 816 in which a blockchain (e.g., blockchain 810) isreplicated across the blockchain network 816.

In one example, a user 802 a can use the client terminal 804 a to send aweb service request (e.g., a request to deliver a legal notice 820 touser 802 b) to the blockchain network 816. The trusted platform 300implemented on the blockchain network node 818 of the blockchain network816 can process and fulfill the web service request (e.g., delivernotice 820 to the user 802 b via the client terminal 804 b).

The client terminals 804 a and 804 b can include, for example, anysuitable computer, module, server, or computing element programmed toperform methods described herein. In some embodiments, the clientterminals 804 a and 804 b can include a web browser and softwareapplications for providing various functions of the client terminals 804a and 804 b.

The trusted timing module 310 can be configured to generate time stampsbased on national standard timing information (e.g., Greenwich Mean Time(GMT), UTC), or timing information obtained from a global positioningsystem.

In some embodiments, the trusted timing module 310 can be configured togenerate time stamps associated with different users using differentstandard times for courts systems in different regions. For example, thetrusted timing module 310 can generate time stamps associated with afirst user using a first standard time recognized by a first courtsystem associated with the first user, and to generate time stampsassociated with a second user using a second standard time recognized bya second court system associated with the second user, in which thefirst and second users reside in different regions having differentcourt systems.

The trusted identity module 312 can be configured to verify an identityof a user (e.g., users 802 a and 802 b) based on one or more ofidentifiers associated with the user. In some embodiments, theidentifiers can include at least one of the following: (i) a mobilephone number, (ii) a credit card number, (iii) a user ID associated withan online payment system, (iv) a user ID associated with an onlineshopping account, (v) a user ID associated with a music streaming ordownloading account, (vi) a user IDS associated with a movie streamingor downloading account, (vii) a user ID associated with a messaging orchat account, (viii) a user ID associated with an online bankingaccount, (ix) a user ID associated with a ride hailing service, (x) auser ID associated with an online food ordering service, (xi) a socialsecurity number, (xii) a driver's license number, (xiii) a passportnumber, (xiv) a user ID associated with an online gaming service, (xv)an ID issued by a government entity, (xvi) one or more fingerprints,(xvii) one or more voice prints, or (xviii) iris information.

In some embodiments, the trusted identity module 312 can be configuredto verify different users residing in different regions having differentcourt systems by using different identifiers. For example, the trustedidentity module 312 can be configured to verify the identity of a firstuser using at least one of a first set of identifiers recognized by afirst court system associated with the first user, and to verify theidentity of a second user using at least one of a second set ofidentifiers recognized by a second court system associated with thesecond user, in which the first and second users reside in differentregions having different court systems.

In some embodiments, the trusted computing module 314 can include one ormore data processors having a TEE that is isolated from the one or moredata processors' operating system and configured to provide enhancedconfidentiality and integrity of code executing, and data loaded within,the one or more data processors.

In some embodiments, the trusted computing module 314 can be configuredto record information associated with the user in compliance withprivacy laws. For example, the trusted computing module 314 can generatea hash value of the record, and adds a block that includes the recordand the hash value to the blockchain 820 that stores records associatedwith the user 802 a.

In some embodiments, the trusted computing module 314 can be configuredto provide a verified record of the steps/operations performed by theservice of process tool 302 in response to a request for the verifiedrecord associated with the serving of the notice to the party to beserved. The trusted computing module 314 can also provide the verifiedtime stamp, the verified identity, and/or the computation resultassociated with each step/operation of the steps/operations performed bythe service of process tool 302.

In some embodiments, the service of process tool 302 can allow a servingparty (e.g., a plaintiff such as user 802 a) to serve a notice (e.g.,serve summons or other related documents such as notice 820) to a partyto be digitally served (e.g., a defendant such as user 802 b) whilecomplying with the legal requirements for service of process. In someembodiments, the service of process tool 302 can obtain and record averified time stamp, a verified identity, and/or a computation resultfor each step of a number of steps that are performed by the service ofprocess tool 302 for the service of process. The service of process tool302 can obtain the verified time stamp from the trusted timing module310, the verified identity from the trusted identity module 312, andcomputation results from the trusted computing module 314.

In some embodiments, the service of process tool 302 can include atrusted component (not shown) that is configured to be executed in thetrusted execution environment and record the steps performed by theservice of process tool 302 and the verified time stamp, the verifiedidentity, and/or the computation result associated with each step of thesteps. In some embodiments, the trusted component can include a hashcomputation component that is configured to generate hash values of datarepresenting the steps performed by the service of process tool based ona hash algorithm.

In some embodiments, the service of process tool 302 can be configuredto invoke functions of the trusted timing module 310, the trustedidentity module 312, or the trusted computing module 314 through acorresponding application programming interface (API) (e.g., APIs 810,812, and 814) associated with the trusted timing module 310, the trustedidentity module 312, or the trusted computing module 314. In someembodiments, the APIs 810, 812, and 814 can include any suitable APIssuch as Representational State Transfer (REST) web APIs (or RESTfulAPIs) or Simple Object Access Protocol (SOAP)-based web APIs, etc.

In some embodiments, the service of process tool 302 can invoke thetrusted identity module 312 to verify an identity of a first party(e.g., user 802 a) and an identity of a second party (e.g., user 802 b)upon receiving a request from the first party to serve notice to thesecond party. The service of process tool 302 can further invoke thetrusted timing module 310 to verify a timing of placement of the orderby the user, and invoke the trusted computing module 314 to update theblockchain 820 that includes data representing activities associatedwith service of process.

In some embodiments, the service of process tool 302 can be configuredto invoke the trusted identity module 312 to verify that the secondparty is the party who actually received the notice upon completingserving the notice to the second party. The service of process tool 302can be further configured to invoke the trusted timing module 310 toverify a timing of the receipt of the notice by the second party, andinvoke the trusted computing module 314 to update the blockchain 820that includes data representing activities associated with the serviceof process.

In some embodiments, the service of process tool 302 can be configuredto determine a method for serving the notice to the second party basedon one or more communication methods associated with one or moreaccounts of the second party registered on the system, such as by usingone or more e-mail addresses, one or more phone numbers, or one or moremessaging app user identifiers of the second party.

In the example of FIG. 8, in some embodiments, the user 802 a can loginto the trusted platform 300, and the trusted platform 300 can providea menu of available services, or shows a desktop having iconsrepresenting available tools and application programs. The user 802 acan select one of the services, such as service of process, using themenu or the icons, upon which the service of process tool 302 isexecuted. The user 802 a can use the service of process tool 302 toserve The trusted platform 300 can be associated with the blockchain816, and the service of process tool 302 can invoke the trustedcomputing module 314 to process blockchain data and record relevant datain the blockchain 816. The service of process tool 302 can be used todeliver documents other than court ordered notices.

FIG. 9 is a flowchart illustrating an example of a process 900 inaccordance with embodiments of this specification. For convenience, theprocess 900 will be described as being performed by a system of one ormore computers, located in one or more locations, and programmedappropriately in accordance with this specification. For example, adistributed system, e.g., the system 800 of FIG. 8, appropriatelyprogrammed, can perform the process 900.

At step 902, a request is received at a blockchain-based application fordelivering a notice (e.g., notice 820) associated with a legal actionfrom a serving party (e.g., user 802 a) to a party to be served (e.g.,user 802 b). In some embodiments, the blockchain-based application issupported by a blockchain-based platform. For example, theblockchain-based application can be the service of process tool 302, andthe blockchain-based platform can be the blockchain-based trustedplatform 300. In some embodiments, the user 802 a generates the requestby selecting a function of the blockchain-based application fordelivering legal notices. In some embodiments, the request can includean identity associated with the serving party and an identity associatedwith the party to be served. The request can also include the contactinformation of the party to be served.

At step 904, it is determined whether the serving party is a registereduser of the blockchain-based application or the blockchain-basedplatform. In some embodiments, the blockchain-based application caninvoke a trusted identity module (e.g., trusted identity module 312) toverify the identity of the serving party to determine whether theserving party is a registered user of the blockchain-based applicationor the blockchain-based platform. In some embodiments, the determinationcan be based on matching the identity of the serving party with anidentity included in registration information of the serving partyrecorded on a blockchain (e.g., blockchain 810). In some embodiments,registration information of users (e.g., users 802 a and 802 b) that arerecorded on the blockchain can include identity information of theusers. The identify information can include user ID of an accountassociated with the user, biometric identity information (e.g., fingerprint, facial data, retina print), and digital secret key associatedwith the user, etc.

In some embodiments, the registration information can include availablecommunication methods associated with the users. The availablecommunication methods can include at least one of the following: e-mail,telephone call, or instant messaging. For example, registrationinformation for user 802 a can include an e-mail address associated withthe user 802 a, a telephone number associated with user 802 a, and/or aninstant messaging account associated with the user 802 a. In someembodiments, the identity information and the available communicationmethods in the registration information can be verified for the usersduring registration to determine that they are genuine.

In some embodiments, the blockchain-based application can invoke atrusted computing module (e.g., trusted computing module 314) to updatethe blockchain that includes data representing events or activitiesassociated with the process 900. For example, the blockchain-basedapplication can invoke the trusted computing module to record data ofone or more computing results of the determination in step 904 in theblockchain.

If it is determined that the serving party is not a registered user ofthe blockchain-based application, the process 900 proceeds to step 906in which a notification is sent to the serving party to indicate thatthe serving party is not a registered user of the blockchain-basedapplication. If it is determined that the serving party is a registereduser of the blockchain-based application, the process 900 proceeds tostep 908.

At step 908, a time that the request is received on the blockchain isrecorded. In some embodiments, the blockchain-based application caninvoke a trusted timing module (e.g., trusted timing module 310) togenerate a time stamp associated with the request. In some embodiments,the trusted timing module 310 can generate the time stamp associatedwith the request from the serving party (e.g., user 802 a) using astandard time (e.g., UTC) recognized by a court system associated withthe serving party. In some embodiments, the trusted timing module 310can generate the time stamp based on timing information obtained from aglobal positioning system.

In some embodiments, the time and a digital signature generated based onthe time can be added to the notice. In some embodiments, the digitalsignature can include the time that is signed using a private keyassociated with the serving party.

At step 910, it is determined whether the party to be served is aregistered user of the blockchain-based application. In someembodiments, the blockchain-based application can invoke a trustedidentity module (e.g., trusted identity module 312) to verify theidentity of the party to be served to determine whether the party to beserved is a registered user of the blockchain-based application. In someembodiments, the determination can be based on matching the identity ofthe party to be served with an identity included in registrationinformation of the party to be served recorded on the blockchain (e.g.,blockchain 810). If it is determined that the party to be served is nota registered user of the blockchain-based application, the process 900proceeds to step 912 in which a notification is sent to the servingparty to indicate that the party to be served is not a registered userof the blockchain-based application. If it is determined that the partyto be served is a registered user of the blockchain-based application,the process 900 proceeds to step 914.

At 914, one or more manners of delivering the notice are identified ifit is determined that the party to be served is a registered user of theblockchain-based application. In some embodiments, the identifying canbe based on one or more available communication methods included in theregistration information of the party to be served. For example, theblockchain-based application can determine that the availablecommunication methods for the party to be served include e-mail,telephone call, and/or instant messaging, and identify an e-mailaddress, a telephone number, and an instant messaging account associatedwith the party to be served.

At 916, it is determined whether the party to be served is logged on toan account registered with the blockchain-based application afterdelivering the notice to the party to be served. If it is determinedthat the party to be served is not logged on to the account, the process900 proceeds to step 918 in which a notification is sent to the servingparty to notify that the party to be served is offline. In someembodiments, the notification can be sent to the account associated withthe serving party to notify that the party to be served is offline. Insome embodiments, if it is determined that the party to be served is notlogged on to the account, the blockchain-based application can attemptto deliver the notice to the party to be served at another time. If itis determined that the party to be served is logged on to the account,the process 900 proceeds to step 920.

At step 920, the notice is delivered to the party to be served. In someembodiments, if the party to be served is logged on to the account ofthe blockchain-based application or the blockchain-based platform usinga service that has a built-in communication method, the applicationattempts to deliver the notice to the party to be served using thebuilt-in communication method. For example, if the applicationdetermines, at 916, that the party to be served is logged on to aninstant messaging account provided by the platform, the application candeliver the notice to the instant messaging account of the party to beserved. In some embodiments, the notice can be delivered to the party tobe served based on at least one of the one or more manners of deliveringthe notice determined at step 914. In some embodiments, the notice canbe delivered to the party to be served simultaneously or otherwise inparallel using the communication methods that are identified at step914. For example, the notice can be sent to the party to be served bysimultaneously sending the notice to the e-mail address of the party tobe served, calling the telephone number of the party to be served, andsending an instant message to the instant messaging account of the partyto be served.

In some embodiments, the notice can be delivered to the party to beserved by making a contract call to a smart contract (not shown)executing on a blockchain node (e.g., blockchain node 818) that theblockchain-based application resides. The smart contract can includedefined functions or operations to retrieve, generate, store, orotherwise manipulate or manage blockchain data. In some embodiments, thesmart contract can be automatically executed when some predeterminedexecution conditions are met. For example, when the one or more mannersof delivering the notice are identified at step 914, the smart contractcan self-execute and deliver the notice to the party to be served usingthe available communication methods.

At step 922, an acknowledgement is received from the party to be servedfor accepting the notice. For example, if the notice is delivered to aninstant messaging account of the party to be served, when the party tobe served reads the message containing the notice, the instant messagingprogram can generate a read receipt. In some embodiments, the noticerequests the party to be served to manually acknowledge receipt by,e.g., clicking on a button in the message indicating receipt of thenotice, or sending a reply message acknowledging receipt.

At step 924, after receiving an acknowledgement from the party to beserved for accepting the notice, a notification is sent to the servingparty to notify that the notice is delivered. In some embodiments, thenotification can be sent to an account associated with the serving partyto notify that the notice is delivered. In some embodiments, theacknowledgement can be delivered to the serving party based on theavailable communication methods included in the registration informationof the serving party.

In some embodiment, the time the acknowledgement is received can berecorded on the blockchain. For example, the blockchain basedapplication can invoke the trusted timing module 310 to verify a timingof the receipt of acknowledgement and record the time that theacknowledgement is received upon verification.

In some embodiments, the blockchain-based application can invoke thetrusted identity module 312 to verify that party to be served is theparty who actually received the notice. For example, theblockchain-based application can verify an identity information or adigital signature included in the acknowledgement to determine whetherthe acknowledgement is received from the party to be served.

In some embodiments, the blockchain-based application can invoke thetrusted computing module 314 to update the blockchain that includes datarepresenting associated with the process 900. For example, theblockchain-based application can invoke the trusted computing module 314to record data of computing results of any one of steps 902-924 in theblockchain.

The following describes an example in which a user uses the legaldocumentation tool 306 to fill out an electronic form. In this example,each step of filling out the electronic form is recorded to a blockchainand is verifiable. A unique ID is generated and embedded in the digitalcontent of the electronic form at each step. The unique ID can be usedto retrieve the recordings of each step.

The embodiments of the legal documentation tool enables a user and aservice provider to complete an electronic form, e.g., a legal documentneeded as part of the process of providing a service to the user. One ofthe problems with conventional technologies is that the digital contentof an electronic form is easy to tamper with. It is also difficult toverify the identity and the time when the digital form was filled out.Thus, some of the legal documentations require a user and/or a serviceprovider to fill out one or more paper forms, which usually requires theuser and/or service provider to meet in person and complete the formtogether. Completing the paper form offline leads to low serviceefficiency and difficulties of keeping the paper forms.

The techniques described in this specification produce several technicaleffects. In some embodiments, the system records each step for fillingout an electronic form of a service, such as the user filling out theform at each step, the time at each step, and the digital content on theelectronic form at each step. The record enables the verification ofeach step for filling out the electronic form, and thus prevents theuser from tampering with the content of the electronic form, forging theelectronic form, or providing fraudulent information in filling out theelectronic form. The data integrity and security for the electronic formrequired for the service can be enhanced. With the enhanced dataintegrity and security, the electronic form can replace the paper formwhich may be required to complete the service using the previoustechnologies.

In some embodiments, a unique ID is generated and embedded in thedigital content of the electronic form for each step. The unique ID canbe extracted from the electronic form to retrieve the time and thedigital content of the electronic form in each step from the blockchain.Thus, the status of the electronic form in each step can be looked upand verified. The authenticity of the electronic form is furtherenhanced.

FIG. 10 is a diagram illustrating an example of a system 1000 forproviding legal documentation in accordance with embodiments of thisspecification. The system 1000 implements a legal documenting processbased on a blockchain network. In general, a legal documenting processis a procedure by which a user and/or a service provider fill out one ormore electronic forms of a legal documentation corresponding to aservice provided by the service provider.

As an example, the system 1000 includes client terminals 1004 a and 1004b (used by a user 1002 and a service provider 1004, respectively), ablockchain-based trusted platform 300, and a blockchain network 1016. Asshown, the blockchain-based trusted platform 300 includes a legaldocumentation tool 306, APIs 810, 812, and 814, a trusted timing module310, a trusted identity module 312, and a trusted computing module 314.Note that the blockchain-based trusted platform 300 is shown to includethe legal documentation tool 306 for illustrative purposes only. Theblockchain-based trusted platform 300 can include any suitable number oftools, such as a service of process tool (e.g., service of process tool302 of FIG. 3), dispute resolution tool (e.g., dispute resolution tool304 of FIG. 3), and a judgement execution tool (e.g., judgementexecution tool 308), etc. In some embodiments, the trusted platform 300is associated with one of the nodes 1014 of the blockchain network 1016in which a blockchain (e.g., blockchain 1010) is replicated across theblockchain network 1016.

In one example, a user 1002 can use the client terminal 1004 a to send aservice request (e.g., a request to fill out a legal documentation for aservice) to the blockchain network 1016. The trusted platform 300implemented on the blockchain network node 1014 of the blockchainnetwork 1016 can process and fulfill the service request (e.g., arequest to fill out a legal documentation for a service).

In some embodiments, the legal documentation tool 306 can be configuredto adopt the SM2 algorithm which is a public key cryptographic algorithmbased on elliptic curves, to encrypt the data communications and verifythe identities. In some embodiments, access levels can be specified forthe contents recorded by the legal documentation tool 306. Some recordedcontents can only be accessed by the personnel with the specified accesslevel.

The client terminals 1004 a and 1004 b can include, for example, anysuitable computer, module, server, or computing element programmed toperform methods described herein. In some embodiments, the clientterminals 1004 a and 1004 b can include a web browser and softwareapplications for providing various functions of the client terminals1004 a and 1004 b.

The trusted timing module 310 can be configured to obtain a time from atime source such as the National Time Service Center (NTSC), UTC, GPST,GLONASS Time (GLONASST), Galileo System Time (GST), or BeiDou Time(BDT). In some embodiments, the blockchain network can obtain the timefrom a single source, such that all the blockchain nodes of theblockchain network can be synchronized with the same time.

In some embodiments, the trusted timing module can be configured togenerate time stamps based on at least one of (i) national standardtiming information, or (ii) timing information obtained from a globalpositioning system.

In some embodiments, the trusted timing module 310 can be configured togenerate time stamps associated with different users using differentstandard times for court systems in different regions. For example, thetrusted timing module 310 can generate time stamps associated with afirst user using a first standard time recognized by a first courtsystem associated with the first user, and to generate time stampsassociated with a second user using a second standard time recognized bya second court system associated with the second user, in which thefirst and second users reside in different regions having differentcourt systems.

The trusted identity module 312 can be configured to verify an identityof a user or an identity of a service provider (e.g., user 1002 andservice provider 1004) based on one or more of identifiers associatedwith the user or the service provider. In some embodiments, theidentifiers can include at least one of the following: (i) a mobilephone number, (ii) a credit card number, (iii) a user ID associated withan online payment system, (iv) a user ID associated with an onlineshopping account, (v) a user ID associated with a music streaming ordownloading account, (vi) a user IDS associated with a movie streamingor downloading account, (vii) a user ID associated with a messaging orchat account, (viii) a user ID associated with an online bankingaccount, (ix) a user ID associated with a ride hailing service, (x) auser ID associated with an online food ordering service, (xi) a socialsecurity number, (xii) a driver's license number, (xiii) a passportnumber, (xiv) a user ID associated with an online gaming service, or(xi) an ID issued by a government entity.

In some embodiments, the trusted identity module 312 can be configuredto verify different users residing in different regions having differentcourt systems by using different identifiers. For example, the trustedidentity module 312 can be configured to verify the identity of a firstuser using at least one of a first set of identifiers recognized by afirst court system associated with the first user, and to verify theidentity of a second user using at least one of a second set ofidentifiers recognized by a second court system associated with thesecond user, in which the first and second users reside in differentregions having different court systems.

In some embodiments, the trusted computing module 314 can include one ormore data processors having a TEE that is isolated from the one or moredata processors' operating system and configured to provide enhancedconfidentiality and integrity of code executing, and data loaded within,the one or more data processors.

In some embodiments, the trusted computing module 314 can be configuredto record information associated with the user in compliance withprivacy laws. For example, the trusted computing module 314 can generatea hash value of the record, and adds a block that includes the recordand the hash value to a blockchain 1010 that stores records associatedwith the user 1002.

In some embodiments, the legal documentation tool 306 can be configuredto perform a plurality of steps to process information for conducting aservice, and for each step of at least some of the plurality of steps,the legal documentation tool 306 can be configured to invoke the trustedcomputing module to process blockchain data to update a blockchain torecord information including at least one of a verified time stampgenerated by the trusted timing module or a verified identity determinedby the trusted identity module, where the verified time stamp representsa timing of an event in the information process for conducting theservice, and the verified identity represents an identity of the user.

In some embodiments, the trusted computing module 314 can be configuredto provide a verified record of the steps/operations performed by thelegal documentation tool 306 in response to a request for the verifiedrecord associated with the legal documentation. The trusted computingmodule 314 can also provide the verified time stamp, the verifiedidentity, and/or the computation result associated with eachstep/operation of the steps/operations performed by the legaldocumentation tool 306.

In some embodiments, the legal documentation tool 306 can allow a userto fill out an electronic legal documentation while complying with thelegal requirements for legal documenting process. In some embodiments,the legal documentation tool 306 can obtain and record a verified timestamp, a verified identity, and/or a computation result for each step ofa number of steps that are performed by the legal documentation tool 306for the legal documenting process. The legal documentation tool 306 canobtain the verified time stamp from the trusted timing module 310, theverified identity from the trusted identity module 312, and computationresults from the trusted computing module 314.

In some embodiments, the legal documentation tool 306 can include atrusted component (not shown) that is configured to be executed in thetrusted execution environment and record the steps performed by thelegal documentation tool 306 and the verified time stamp, the verifiedidentity, and/or the computation result associated with each step of thesteps. In some embodiments, the trusted component can include a hashcomputation component that is configured to generate hash values of datarepresenting the steps performed by the legal documentation tool basedon a hash algorithm.

In some embodiments, the legal documentation tool 306 can be configuredto invoke functions of the trusted timing module 310, the trustedidentity module 312, or the trusted computing module 314 through acorresponding API (e.g., APIs 810, 812, and 814) associated with thetrusted timing module 310, the trusted identity module 312, or thetrusted computing module 314. In some embodiments, the APIs 810, 812,and 814 can include any suitable APIs such as REST web APIs (or RESTfulAPIs) or SOAP-based web APIs, etc.

In some embodiments, the legal documentation tool 306 can invoke thetrusted identity module 312 to verify an identity of a user (e.g., user1002) upon receiving a request for providing the service initiated froman account of a user associated with a blockchain-based application. Thelegal documentation tool 306 can further identify one or more electronicforms to be filled out and submitted in a plurality of steps forproviding the service.

In some embodiments, at each step of the plurality of steps, the legaldocumentation tool 306 can invoke the trusted timing module 310 togenerate a time that the step is performed, and generate a uniqueidentifier (ID) based on the time that the step is performed and digitalcontent on the electronic form at the time. The legal documentation tool306 can further invoke the trusted computing module to record the uniqueID, the time, and the digital content on the blockchain. The legaldocumentation tool 306 can then embed the unique ID in the digitalcontent at the time by changing one or more attributes associated withthe digital content to be representative of the unique ID, where theembedding produces information-embedded digital content that enablesretrieval of the time and the digital content from the blockchain basedon the unique ID. The legal documentation tool 306 can further invokethe trusted computing module to record the information-embedded digitalcontent to the blockchain.

FIG. 11 is a flowchart illustrating an example of a process 1100 thatcan be executed in accordance with embodiments of this specification.The process 1100 can be performed by one or more blockchain nodes or acomputing device communicably coupled to the one or more blockchainnodes. For clarity of presentation, the description that followsgenerally describes process 1100 in the context of the other figures inthis description. However, it will be understood that process 1100 canbe performed, for example, by any system, environment, software, andhardware, or a combination of systems, environments, software, andhardware, as appropriate. In some embodiments, various steps of process1100 can be run in parallel, in combination, in loops, or in any order.

At 1102, a request for a service is received. The service can be apublic service provided by a government agency, a business serviceprovided by a business service provider. For example, the service can bea driver's license renewal service, tax registration service, marriagelicense service, bank account opening service, residence ID cardservice, apartment leasing service, etc. In some embodiments, the usercan initiate a request for a service by accessing the legaldocumentation tool 306 of the trusted platform 300 from the user'saccount of the legal documentation tool 306 or another blockchain-basedapplication that hosts the legal documentation tool 306. For example,the user can open the legal documentation tool 306 on the user's clientterminal and logging into the account. The available services can thenbe displayed on the user's client terminal and the user can initiate therequest by selecting a desired service.

In some embodiments, a second request for handling the user's servicerequest can be initiated from an account of a service providerassociated with the legal documentation tool 306. The second request forhandling the user's request can be examining the user's paperwork,making a decision on the user's paperwork, endorsing the user'ssignature, sending supplemental document requests after examining theuser's paperwork, etc.

At 1104, an identity is verified. The identity can be the identity ofthe user or a representative of the service provider. In someembodiments, the identity can be included in the request for theservice.

In some embodiments, the legal documentation tool 306 invokes thetrusted identity module 312 to verify the identity of the user or therepresentative of the service provider. In some embodiments, the user orthe representative can use biometric information for registration. Whenthe user or the representative accesses the legal documentation tool306, the user or the representative can be asked to use fingerprint,voice, iris, or facial recognition to verify his/her identity. Afterentering the corresponding biometric information through a sensor, thetrusted identity module 312 can match the biometric information toregistration information stored in memory to verify if the user orrepresentative is authorized to use the legal documentation tool 306.

At 1106, one or more electronic forms to be filled out and submitted forproviding a service are identified. The one or more electronic forms canbe the digital paperwork needed by the service provider for providingthe service. For example, the electronic form can be an applicationform, a service agreement, a membership renewal form, a rentalagreement, a purchase order, etc. The electronic form can include one ormore online pages.

At 1108, it is determined that if there is an additional step to beperformed on the electronic form. In some embodiments, filling out anelectronic form can include multiple steps. For example, filling out aleasing agreement can include signing each page of the rental agreement.Signing each signature or initial can be a separate step of filling outthe agreement. The steps can be performed by the user, the serviceprovider, or both the user and the service provider. For example, theuser can sign on a page of the electronic form in one step, and inanother step, the service provider can sign on the same page to endorsethe user's signature. In some embodiments, the user and the serviceprovider can both access the legal documentation tool 306 to perform thesteps interactively, e.g., one party can remain logged in to wait forthe other party to complete his/her signature before the party canendorse or countersign. In some embodiments, the user and the serviceprovider can logged in separately to perform their own steps of theinformation documentation process. If there is an additional step toperform, the process 1100 proceeds to 1110. Otherwise, the process 1100proceeds to 1116.

At 1110, a unique ID is generated based on a time that the step isperformed and digital content on the electronic form at the time. Theunique ID can be used to uniquely identify the user. In someembodiments, the unique ID can include the user's identity informationdigitally signed by its private key. The user can then be identified bydecrypting the digital signature with the public key corresponding tothe user and verified by comparing the decrypted information to theuser's trusted identity recorded on the blockchain. In some embodiments,the unique ID can be generated based on the time and the digital contenton the electronic form filled in by the user at the time. In someembodiments, the unique ID can be generated based on the time and theelectronic form.

In some embodiments, the unique ID can be embedded in the digitalcontent filled in by the user. In some embodiments, a second unique IDcan be generated based on the time that a second step is performed andthe digital content on the electronic form filled in by the serviceprovider at the time. The second unique ID can be embedded in thedigital content filled in by the service provider.

In some embodiments, at least a portion of the content, including thetime that the step is performed and the digital content on theelectronic form at the time, can be used to generate the unique ID, suchas by generating a hash value based on the portion of the content. Insome embodiments, the content used to generate the unique ID furtherincludes the identity of the user or the service provider.

In some embodiments, the unique ID can be encrypted or hashed to enhancethe robustness and security. For example, the encryption can beperformed based on public key encryption using a user's or a serviceprovider's public key. In some embodiments, the encryption can also beperformed based on encryption schemes such as the Arnold scramblingencryption to adapt to the embedding technique used. By performingencryption, even if an attacker extracts the digital watermark, theassociated unique ID cannot be decrypted if the encryption scheme orencryption key is unknown to the attacker.

At 1112, the unique ID, the time, and the digital content are recordedon the blockchain. In some embodiments, the unique ID, the time, and thedigital content can be recorded as a transaction on the blockchain inthe form of a key-value pair, where the key is the unique ID, and thevalue includes the time and the digital content. The unique ID can thenbe used to retrieve the value including the time and the digitalcontent. In some embodiments, a blockchain network can adopt acontent-addressed tree structure, such as a Merkle Patricia Tree orfixed depth Merkle tree. In some embodiments, each blockchain node of ablockchain network associated with the trusted platform can store aportion of block data or state data. For example, a blockchain node canbe a light weight node, which stores only the unique ID and the time,but not the digital content, as compared to a full node that stores theunique ID, the time, and the digital content. In some embodiments, theblockchain network can include one or more shared storage nodes thatstore historic state data, while other regular blockchain node onlystores current state data to save on storage.

At 1114, the unique ID is embedded in the digital content. In someembodiments, each step corresponds to a page of the electronic form. Aunique ID can be embedded in each page of the electronic form. In someembodiments, the unique ID can be embedded in the digital content bychanging one or more attributes associated with the digital content tobe representative of the unique ID, where the embedding producesinformation-embedded digital content that enables retrieval of the timeand the digital content from the blockchain based on the unique ID. Insome embodiments, the unique ID can be invisibly embedded. The embeddedunique ID can be considered invisible if its addition is not noticeableor visible to naked eyes. In other words, the unique ID can beconsidered invisible if the visual difference between the digitalcontent before embedding the unique ID and after embedding the unique IDis not apparent to an unaided human eye. The unique ID can be embeddedin digital content, foreground of the digital content, or background ofthe digital content. The foreground of the digital content can be a filmor screen attached or integrated to a platform where the digital contentis displayed. The foreground of the digital content can also be a layerincluding the unique ID that is configured not to be rendered by aviewing application. The background of the digital content can be abackground of a visual representation of an electronic file containingthe digital content that is rendered on a display.

In some embodiments, the invisible embedding of digital content can beperformed based on digital watermarking. Digital watermarking is atechnique of using data carriers to embed the unique ID. Data carrierscan include text, images, or electronic media. The unique ID can beembedded in the data carriers as an invisible digital watermark. When aquery for a digital content occurs, the unique ID can be extracted fromthe data carriers to retrieve the digital content corresponding to theunique ID.

Digital watermarking techniques can include background brightnessmasking, illuminance masking, texture masking, spatial masking andfrequency masking. Different techniques can be based on differentdigital watermarking algorithms. In some embodiments, digital watermarkembedding can be based on human visual system (HVS) characteristics toachieve visual imperceptibility or invisibility. For example, the humaneyes are more sensitive to the changes in the low intensity pixels thanthe higher intensity ones. In illuminance masking, pixels of digitalcontent can be scanned to identify those with high intensity levels. Thehigh intensity pixels can be used to embed the digital watermark.Modifications made to the high intensity pixels can be difficult toperceive by human eyes, such that the digital watermark can beconsidered invisibly embedded. Using illuminance masking, the digitalwatermark can be embedded in the entire digital content or a portion ofthe digital content. For example, if the digital content is textualcontent, the digital watermark can be embedded in a letter, a word, asentence, or all the way up to the entire textual content.

As another example, in texture masking, the more complex the texture is,the more difficult the human eyes can discern the change of the texture.Therefore, the digital watermark can be embedded to a portion of adigital image or background of digital content with more complex textureto be less perceptible by human eyes.

As yet another example, digital watermarking can be performed based onfrequency masking by transforming the digital content to frequencydomain coefficients based on mathematical transformations such asdiscrete cosine transform (DCT), discrete wavelet transform (DWT), orArnold transform. In frequency masking, intermediary or low frequencycoefficients are normally modified according to the watermarkinformation. Those frequency ranges are less impactful to the appearanceof the original content. The digital watermark (i.e., the unique ID) canbe in the form of a character string. The character string can beconverted to a single binary string. Each bit can be embedded to adjustlower frequency coefficients depending on the transformation techniqueused. In frequency masking, the digital watermark can be dispersed tothe whole digital content, which can increase robustness andinvisibility. Other example mathematical transformations for performingdigital watermarking can include DWT and singular value decomposition(DWT-SVD), least significant bit (LSB), or highly undetectablesteganography (HUGO).

In some embodiments, more than one digital watermarking technique can beused to embed multiple layers of digital watermarks to the data carrier.In such cases, an index of the layers of digital watermarking can alsobe generated and embedded in the data carrier. The index can be used tomore easily extract digital watermarks from the data carriers. In someembodiments, the unique ID can be randomized or mixed with a randomsignal before embedding to the data carrier.

In some examples, the digital content can be textual content. Theembedded unique ID can be considered invisible if it does not materiallychange the content. The content can be considered not materially changedif the embedded information does not alter the meaning of the text. Forexample, the original text is “he becomes a monster after seven years,”and the information embedded text is “he has become a ‘monster’ afterseven years.” The information embedded in the added text is notconsidered as materially changed from the original text, since themeaning of the text stays the same. In this example, the unique ID canbe embedded in the quotation marks, or the auxiliary word “has,”according to the techniques described herein. In some embodiments, theunique ID can be embedded in spaces or function words such as articles,prepositions, conjunctions, and auxiliaries, which do not normally alterthe material meaning of textual content.

In some embodiments, a plurality of unique IDs can be used to track theupdates of the textual content. For example, one or more unique IDs canbe generated based on timestamps corresponding to one or more digitalcontent updates recorded on the blockchain. When a content update isperformed and recorded on the blockchain, a unique ID including thecorresponding timestamp can be embedded in at least a portion of theupdated content. The timestamps in the unique IDs extracted from thedigital content can form a timeline of creation and update history ofthe digital content. The timeline can be used as evidence of the contentdevelopment process, and compared to the update history recorded on theblockchain to authenticate authorship of the textual content.

In some embodiments, the unique ID can be embedded in characteristicsinformation of textual or image content. Example characteristicsinformation can include color, brightness, and transparency of text orimage. For example, text or image color can be encoded based on a red,green, and blue (RGB) color model. The unique ID can be embedded toslightly change the RGB value combination not noticeable by naked eyes.As another example, the unique ID can be embedded in YCbCr formattedtext or image, where Y represents the luminance signal, Cb representschrominance blue signal, and Cr represents chrominance red signal. Theluminance signal is relatively insensitive to information embedding,which can be preferably used to invisibly embed the unique ID.

In some embodiments, the unique ID can be embedded in punctuations oftextual content. For example, in the text “after seven years, he becomesa ‘monster’,” the unique ID can be embedded in the encoding of thecommas and quotation marks.

In some embodiments, the unique ID can be embedded in fonts used bytextual content. Fonts can be encoded using Unicode such as UTF-8. TheUTF-8 is based on variable width character encoding, which uses one tofour 8-bit bytes. Embedding the unique ID in some of the bits mayslightly change pixel positions, size, angle, shape of font orpunctuations invisible to the naked eye. For example, pixels of textfonts and punctuations can be encoded with redundancy. Redundancy isnormally added to pixels for error checking in data communications.Redundancy such as check bits can be used to check data integrity at thereceiver end. If the check bits are not consistent with the rest of theinformation bearing pixels when they arrive at the receiver, thereceiver can ask the sender to retransmit the content. The unique ID canbe randomly embedded in redundant pixels or embedded in redundant pixelsin fixed positions. It is to be understood that the unique ID can alsobe invisibly embedded in other hidden characteristics of fonts orpunctuations.

In some embodiments, the unique ID can be embedded in forms or tableswithin or containing the digital content. Those embodiments areespecially suitable for right authentication of text or images insertedin online forms or tables. For example, an online form can be a formdefined in the Hypertext Markup Language (HTML) definition of a webpage(such as by using the “<form>” tag) and rendered by a browser programdisplaying the webpage. Similarly, an online table can be a tabledefined in the Hypertext Markup Language (HTML) definition of a webpage(such as by using the “<table>” tag) and rendered by a browser programdisplaying the webpage. The unique ID can be invisibly embedded invalues associated with color, shade, cell size, or other properties ofthe forms or tables.

In some cases, the unique ID can be embedded in electronic media thatcan be used to display or publish digital content. For example, theunique ID can be embedded in background textures of webpages orelectronic files such as MICROSOFT WORD, POWERPOINT, or ADOBE PDF.

At 1116, the information-embedded digital content is recorded to theblockchain. In some embodiments, a correlation between the unique ID andthe information-embedded digital content can be established, and theinformation-embedded digital content can be retrieved from theblockchain based on querying the unique ID.

FIG. 12 is a diagram illustrating an example of a system 1200 forproviding dispute resolution in accordance with embodiments of thisspecification. The system 1200 implements dispute resolution based on ablockchain network. Generally, the system 1200 allows two or moreparties in dispute to find one or more potential solutions to thedispute from multiple dispute resolution providers (e.g., disputemediators) in a convenient manner.

As an example, the system 1200 includes client terminals 1204 a and 1204b (used by users 702 a and 702 b, respectively), a blockchain-basedtrusted platform 300, and a blockchain network 1216. The system 1200communicates with several dispute resolution providers 1206 a-1206 m. Asshown, the blockchain-based trusted platform 300 includes a disputeresolution tool 304, APIs 810, 812, and 814, a trusted timing module310, a trusted identity module 312, and a trusted computing module 314.Note that the blockchain-based trusted platform 300 is shown to includethe dispute resolution tool 304 for illustrative purposes only. Theblockchain-based trusted platform 300 can include any suitable number oftools, such as a service of process tool (e.g., service of process tool302 of FIG. 3), a legal documentation tool (e.g., legal documentationtool 306) and a judgement execution tool (e.g., judgement execution tool308), etc. In some embodiments, the trusted platform 300 is associatedwith one of the nodes 1214 of the blockchain network 1216 in which ablockchain (e.g., blockchain 1210) is replicated across the blockchainnetwork 1216.

In one example, a user 1202 a can use client terminal 1204 a to send aweb service request (e.g., a request to resolve a legal dispute) to theblockchain network 1216. The trusted platform 300 associated with theblockchain network node 1214 of the blockchain network 1216 can processand fulfill the web service request (e.g., provide dispute resolutionsto user 1202 a via client terminal 1204 a). As another example, user1202 a and user 1202 b can jointly submit a legal dispute involving user1202 a and user 1202 b to the trusted platform 300. The trusted platform300 can invite dispute resolutions from multiple dispute resolutionprovider 1206 a-1206 m and identify one or more dispute resolutions thatboth user 1202 a and user 1202 b agree on.

The client terminals 1204 a and 1204 b can include, for example, anysuitable computer, module, server, or computing element programmed toperform methods described herein. In some embodiments, the clientterminals 1204 a and 1204 b can include a web browser and softwareapplications for providing various functions of the client terminals 704a and 704 b.

In some embodiments, the dispute resolution tool 304 can provide one ormore potential solutions to a dispute between at least a first party(e.g., user 1202 a) and a second party (e.g., user 1202 b). In someembodiments, the dispute resolution tool 304 can invoke a trustedidentity module (e.g., trusted identity module 312) to verify anidentity of the first party, verify an identity of the second party, andverify identities of a number of dispute resolution providers (e.g.,dispute resolution provider 1206 a-1206 m). The dispute resolution tool304 can further send information related to the dispute to the number ofdispute resolution providers.

In some embodiments, the dispute resolution tool 304 can receivepotential solutions for the dispute from the number of disputeresolution providers 1206 a-1206 m, and send the potential solutions tothe first party and the second party. In some embodiments, the disputeresolution tool 304 can receive responses from the first and secondparties and determine whether there is at least one resolution acceptedby both parties based on the responses. For example, the disputeresolution tool 304 can receive a first set of potential disputeresolutions from the first party and a second set of potential disputeresolutions from the second party. The dispute resolution tool 304 candetermine whether there is at least one common dispute resolution forthe first and the second sets. If it is determined that there is nocommon dispute resolution, the dispute resolution tool 304 can determinethat none of the potential resolutions are acceptable to the first andsecond parties.

In some embodiments, the dispute resolution tool 304 can update ablockchain (e.g., blockchain 1210) to record data associated with theservice provided by the dispute resolution tool 304. For example, thedispute resolution tool 304 can update the blockchain 1210 to recorddata representing the dispute between the parties 1202 a and 1202 b andthe potential solutions provided by the dispute resolution providers1206 a-1206 m. The dispute resolution tool 304 can update the blockchain1210 to record data representing identities of the parties 1202 a and1202 b that are in dispute and identities of the dispute resolutionproviders 1206 a-1206 m.

In some embodiments, the dispute resolution tool 304 can update theblockchain 1210 to record data representing a first time stampindicating when the information about the dispute was sent to thedispute resolution providers 1206 a-1206 m and a second time stampindicating when each of the dispute service providers 1206 a-1206 mprovided a potential dispute resolution. In some embodiments, thedispute resolution tool 304 can update the blockchain 1210 to recorddata representing a first time stamp indicating when the potentialdispute resolutions were sent to the first party 1202 a, a second timestamp indicating when the potential dispute resolutions were sent to thesecond party 1202 b, a third time stamp indicating when the first party1202 a provided a response to the potential dispute resolutions, and afourth time stamp indicating when the second party 1202 b provided aresponse to the potential dispute resolutions.

In some embodiments, the dispute resolution tool 304 can receive a firstresponse from the first party 1202 a indicating that at least a firstset of the potential dispute resolutions is acceptable to the firstparty 1202 a, and receive a second response from the second party 1202 bindicating that at least a second set of the potential disputeresolutions is acceptable to the second party 1202 b. The disputeresolution tool 304 can determine whether there is at least one finalpotential solution based on the first and second responses. For example,the dispute resolution tool 304 can determine at least one finalpotential solution based one or more potential solutions that areacceptable to both the first and second parties 1202 a-1202 b.

In some embodiments, the dispute resolution tool 304 can provide anasset to at least one of the dispute resolution providers 1206 a-1206 mwho contributed to the at least one final potential solution acceptableto both the first and second parties 1202 a-1202 b.

In some embodiments, the dispute resolution tool 304 can be configuredto invoke functions of the trusted timing module 310, the trustedidentity module 312, or the trusted computing module 314 through acorresponding API (e.g., APIs 810, 812, and 814) associated with thetrusted timing module 310, the trusted identity module 312, or thetrusted computing module 314. In some embodiments, the APIs 810, 812,and 814 can include any suitable APIs such as REST web APIs (or RESTfulAPIs) or SOAP-based web APIs, etc.

FIG. 13 is a flowchart illustrating an example of a process 1300 forimplementation of a dispute resolution that can be executed inaccordance with embodiments of this specification. For convenience, theprocess 1300 will be described as being performed by a system of one ormore computers, located in one or more locations, and programmedappropriately in accordance with this specification. For example, adistributed system, e.g., the system 1200 of FIG. 12, appropriatelyprogrammed, can perform the process 1300.

At 1302, a request for resolving a dispute between at least a firstparty (e.g., user 1202 a) and a second party (e.g., user 1202 b) isreceived at a blockchain-based application (e.g., the dispute resolutiontool 304). In some embodiments, the request for resolving the disputecan include virtual asset. In some embodiments, the virtual asset is arepresentation of a digital asset that can be defined as either a mediumof exchange or a property that has value in a specific environment, suchas a financial trading environment. In some embodiments, the virtualasset can be offered to a dispute resolution provider (e.g., disputeresolution provider 1206 a-1206 m) as a reward to incentivize disputeresolution providers to study the dispute and propose sensible disputeresolutions.

In some embodiments, the blockchain-based application can receive afirst request from the first party for resolving the dispute. The firstrequest can include a first virtual asset having a first value. Theblockchain-based application can receive a second request from thesecond party for resolving the dispute. The second request can include asecond virtual asset having a second value. In some embodiments, theblockchain-based application can determine the virtual asset based onone of the first virtual asset and the second virtual asset that has ahigher value. For example, if the first virtual asset has a higher valuethan the second virtual asset, the first virtual asset can be determinedas the virtual asset.

In some embodiments, blockchain-based application can store the virtualasset as a deposit. In some embodiments, the blockchain-basedapplication can remove the virtual asset from a first account associatedwith the first party and remove the virtual asset from a second accountassociated with the second party respectively, and store the virtualassets removed from the first account and the second account on theblockchain. Continuing with the above example, if the first virtualasset has a higher value than the second virtual asset, first virtualasset can be determined as a final virtual asset and can be withdrawnfrom the first account associated with the first party. The firstvirtual asset can be also withdrawn from the second account associatedwith the second party. The blockchain-based application can store thetwo pieces of the first virtual asset as a final virtual asset forrewarding the dispute resolution providers.

At 1304, it is determined that whether the first party and the secondparty are registered users of the blockchain-based application. In someembodiments, the determination is based on matching the first identitywith an identity included in registration information of the first partyrecorded on a blockchain and matching the second identity with anidentity included in registration information of the second partyrecorded on the blockchain. In some embodiments, the blockchain-basedapplication can invoke a trusted identity module (e.g., trusted identitymodule 312) to verify the identity of the first party and the identityof the second party. The blockchain-based application can further invokethe trusted identity module to verify identities of a number of disputeresolution providers (e.g., dispute resolution provider 1206 a-1206 m).

In some embodiments, the blockchain-based application can invoke atrusted computing module (e.g., trusted computing module 314) to recorddata representing identities of the parties in dispute and identities ofthe dispute resolution providers.

If it is determined that the first party and the second party are notregistered users of the blockchain-based application, the processproceeds to step 1306 where notification are sent to the first and thesecond parties to notify that first and the second parties are notregistered users. If it is determined that the first party and thesecond party are registered users of the blockchain-based application,the process proceeds to step 1308.

At 1308, a time that the request is received on the blockchain isrecorded. In some embodiments, the blockchain-based application caninvoke a trusted timing module (e.g., trusted timing module 310) torecord a time stamp indicating when the first request is received fromthe first party and a time stamp indicating when the second request isreceived from the second party. In some embodiments, theblockchain-based application can invoke a trusted computing module(e.g., trusted computing module 314) to record data representing thedispute between the parties.

In some embodiments, the blockchain-based application can sendinformation related to the disputer to the number of disputer solutionproviders. In some embodiments, the blockchain-based application 300 caninvoke the trusted timing module 310 to record data representing a timestamp indicating when the information about the dispute was sent to thedispute resolution providers.

At 1310, one or more potential dispute resolutions are received from oneor more dispute resolution providers that are registered with theblockchain-based application (e.g., the dispute resolution tool 304). Insome embodiments, the one or more potential dispute resolutions can berequested to be received within a predetermined time window. In someembodiments, the blockchain-based application (e.g., 304) can invoke thetrusted timing module 310 to record data representing a time stampindicating when each dispute service provider provided a potentialdispute resolution. In some embodiments, the blockchain-basedapplication can invoke the trusted computing module 314 to record datarepresenting the potential solutions provided by the dispute resolutionproviders.

In some embodiments, the blockchain-based application can send thepotential solutions to the first party and the second party. In someembodiments, the blockchain-based application can invoke the trustedtiming module 310 to record data representing a time stamp indicatingwhen the potential dispute resolutions were sent to the first party anda time stamp indicating when the potential dispute resolutions were sentto the second party.

At 1312, a first selection and a second selection are received from thefirst and the second parties. In some embodiments, the first selectionincludes a first set of the one or more potential dispute resolutionsand the second selection includes a second set of the one or morepotential dispute resolutions. In some embodiments, the blockchain-basedapplication can invoke the trusted computing module 314 to record datarepresenting the first selection from the first party and the secondselection from the second party.

At 1314, a time that the first selection is received and a time that thesecond selection is received are recorded on the blockchain. Forexample, the blockchain-based application can invoke the trusted timingmodule 310 to record data representing a time stamp indicating when thefirst party provided the first selection of the potential disputeresolutions, and a time stamp indicating when the second party providedthe first selection of the potential dispute resolutions.

At 1316, it is determined that whether there is at least one commonpotential dispute resolution between the first set of the one or morepotential dispute resolutions and the second set of the one or morepotential dispute resolutions.

If it is determined that there is at least one common potential disputeresolution between the first set of the one or more potential disputeresolutions and the second set of the one or more potential disputeresolutions, the process proceeds to step 1318. If it is determined thatthere is no common potential dispute resolution between the first set ofthe one or more potential dispute resolutions and the second set of theone or more potential dispute resolutions, the blockchain-basedapplication can determine that the none of the potential disputeresolutions are acceptable to the first and second parties, and theprocess proceeds to step 1320.

At 1318, the virtual asset is sent to at least one of the disputeresolution providers that provides the common potential disputeresolutions. For example, the virtual asset can be provided to at leastone of the dispute resolution providers who contributed to the at leastone common potential solution acceptable to both the first and secondparties.

At 1320, a dispute resolution can be received from a statutoryauthorization entity if it is determined that there is no commonpotential dispute resolution between the first set of the one or morepotential dispute resolutions and the second set of the one or morepotential dispute resolutions. In some embodiments, the statutoryauthorization entity is different from the dispute resolution providers.

In some embodiments, the first selection and the second selection arereceived from the first party and the second party respectively within apredetermined time window.

In some embodiments, it is further determined that whether the receiveddispute resolution matches a dispute resolution in the first set of theone or more dispute resolutions and the second set of the one or moredispute resolutions. If it is determined that the dispute resolutionmost closely matches a dispute resolution in the first set of thedispute resolutions selected by the first party, the virtual assetwithdrawn from the second account of the second party can be sent to adispute resolution provider that provides the dispute resolution in thefirst set of the dispute resolutions. If it is determined that that thedispute resolution most closely matches a dispute resolution in thesecond set of the dispute resolutions selected by the second party, thevirtual asset withdrawn from the first account of the first party can besent to a dispute resolution provider that provides the disputeresolution in the second set of the dispute resolutions.

FIG. 14 is a diagram illustrating an example of a system 1400 forjudgment execution in accordance with embodiments of this specification.The system 1400 implements a process to execute court ordered judgementsbased on a blockchain network. In general, system 1400 enables a way toexecute court ordered judgements, in which each judgement specifies adebtor, a creditor, and a judgement amount owed by the debtor to thecreditor.

As an example, the system 1400 includes a debtor 1402, a creditor 1404,one or more payment accounts of the debtor 1406, a judgement amount1408, a payment account of the creditor 1410, a court ordered judgement1412, a blockchain-based trusted platform 300, and a blockchain network1416. As shown, the blockchain-based trusted platform 300 includes alegal documentation tool 306, APIs 810, 812, and 814, a trusted timingmodule 310, a trusted identity module 312, and a trusted computingmodule 314. Note that the blockchain-based trusted platform 300 is shownto include the judgement execution tool 308 for illustrative purposesonly. The blockchain-based trusted platform 300 can include any suitablenumber of tools, such as a service of process tool (e.g., service ofprocess tool 302 of FIG. 3), a dispute resolution tool (e.g., disputeresolution tool 304), and a legal documentation tool (e.g., legaldocumentation tool 306), etc. In some embodiments, the trusted platform300 is one of the nodes 1414 of the blockchain network 1416 in which ablockchain (e.g., blockchain 1410) is replicated across the blockchainnetwork 1416.

In one example, the blockchain-based trusted platform 300 implemented onthe blockchain network node 1414 of the blockchain network 1416 canprocess and execute the court ordered judgement 1412. The judgementamount 1408 can then be transferred from one or more payment accounts ofthe debtor 1406 to the payment account of the creditor 1410.

In some embodiments, the judgement execution tool 308 can be configuredto adopt the SM2 algorithm which is a public key cryptographic algorithmbased on elliptic curves, to encrypt the data communications and verifythe identities. In some embodiments, access levels are specified for thecontents recorded by the judgement execution tool 308. Some recordedcontents can only be accessed by the personnel with the specified accesslevel.

The trusted timing module 310 can be configured to generate time stampsbased on at least one of (i) national standard timing information or(ii) timing information obtained from a global positioning system. Insome embodiments, the blockchain network obtains the time from a singlesource, such that all the blockchain nodes of the blockchain network aresynchronized in time.

In some embodiments, the trusted timing module 310 can be configured togenerate time stamps associated with a first debtor or creditor using afirst standard time recognized by a first court system associated withthe first debtor or creditor, and to generate time stamps associatedwith a second debtor or creditor using a second standard time recognizedby a second court system associated with the second debtor or creditor,in which the first and second debtor(s) or creditor(s) reside indifferent regions having different court systems.

In some embodiments, the trusted identity module 312 can be configuredto verify an identity of a debtor or creditor based on one or more ofidentifiers associated with the debtor or creditor, the identifiersincluding at least one of (i) a mobile phone number, (ii) a credit cardnumber, (iii) a user ID associated with an online payment system, (iv) auser ID associated with an online shopping account, (v) a user IDassociated with a music streaming or downloading account, (vi) a userIDS associated with a movie streaming or downloading account, (vii) auser ID associated with a messaging or chat account, (viii) a user IDassociated with an online banking account, (ix) a user ID associatedwith a ride hailing service, (x) a user ID associated with an onlinefood ordering service, (xi) a social security number, (xii) a driver'slicense number, (xiii) a passport number, (xiv) a user ID associatedwith an online gaming service, or (xi) an ID issued by a governmententity.

In some embodiments, the trusted identity module 312 can be configuredto verify the identity of a first debtor or creditor using at least oneof a first set of identifiers recognized by a first court systemassociated with the first debtor or creditor, and to verify the identityof a second debtor or creditor using at least one of a second set ofidentifiers recognized by a second court system associated with thesecond debtor or creditor, in which the first and second debtor(s) orcreditor(s) reside in different regions having different court systems.

In some embodiments, the trusted computing module 314 includes one ormore data processors having a TEE) that is isolated from the one or moredata processors' operating system and configured to provide enhancedconfidentiality and integrity of code executing, and data loaded within,the one or more data processors.

In some embodiments, the trusted computing module 314 can be configuredto record information associated with the debtor and/or creditor incompliance with privacy laws.

In some embodiments, the blockchain-based judgement execution tool 308can be configured to execute court ordered judgements, in which eachjudgement specifies a debtor (e.g., debtor 1402), a creditor (e.g.,creditor 1404), and a judgement amount owed by the debtor to thecreditor (e.g., judgement amount 1408). The judgement execution tool 308can further invoke the trusted timing module to generate a firstverified time stamp representing a time when the court ordered judgementwas received by the judgement execution tool.

In some embodiments, the judgement execution tool 308 can be configuredto identify one or more assets associated with the debtor. The judgementexecution tool 308 can further collect at least a portion of thejudgement amount from the one or more assets associated with the debtor.The judgement execution tool 308 can be further configured to send thecollected asset to the creditor.

In some embodiments, the judgement execution tool 308 can be configuredto determine one or more payment accounts associated with the debtor,send the court ordered judgement to one or more financial institutionsthat manage the one or more payment accounts associated with the debtor,and request the one or more financial institutions to collect at least aportion of the judgement amount from the payment accounts associatedwith the debtor.

In some embodiments, the judgement execution tool 308 can be configuredto invoke the trusted timing module to generate a second verified timestamp representing a time when the collected asset was sent to thecreditor. The judgement execution tool 308 can further invoke thetrusted computing module to process blockchain data to add a record in ablockchain, in which the record includes information about theidentities of the debtor and creditor, the first and second verifiedtime stamps, and the amount of asset collected from the debtor and sentto the creditor.

In some embodiments, the judgement execution tool 308 can be configuredto perform a plurality of steps to execute a court ordered judgement,and for each step of at least some of the plurality of steps, thejudgement execution tool 308 can be configured to invoke the trustedcomputing module to process blockchain data to update a blockchain torecord information including at least one of a verified time stampgenerated by the trusted timing module or a verified identity determinedby the trusted identity module, where the verified time stamp representsa timing of an event in the execution of the court ordered judgement,and the verified identity represents an identity of the creditor or thedebtor.

In some embodiments, the judgement execution tool 308 can be configuredto process data in the blockchain to provide a verified recordassociated with the plurality of steps of execution of a judgement.

In some embodiments, the judgement execution tool 308 includes a trustedcomponent that is configured to be executed in the TEE and record dataassociated with at least some of the steps performed by the judgementexecution tool 308.

In some embodiments, the trusted component comprises a hash computationcomponent that is configured to generate hash values of datarepresenting the data associated with at least some of steps performedby the judgement execution tool 308 based on a hash algorithm.

In some embodiments, the blockchain based judgement execution tool 308is configured to invoke functions of the trusted timing module, thetrusted identity module, or the trusted computing module through acorresponding application programming interface (API) associated withthe trusted timing module, the trusted identity module, or the trustedcomputing module.

In some embodiments, the blockchain-based judgement execution tool 308can include a client component and a server component, the clientcomponent can be configured to be executed at a client terminal of thedebtor or the creditor, and the server component can be configured to beexecuted at a computer server of the system.

In some embodiments, the judgement execution tool 308 can be configuredto enable the debtor to access the blockchain data to verify that theamount collected from the one or more assets associated with the debtoris consistent with the court ordered judgement.

In some embodiments, the judgement execution tool 308 can be configuredto enable the creditor to access the blockchain data to verify theamount that has been collected from the one or more assets associatedwith the debtor.

In some embodiments, the judgement execution tool 308 can be configuredto enable a representative of a court to access the blockchain data toverify a progress of the execution of the judgement.

FIG. 15 is a flowchart illustrating an example of a process 1500 thatcan be executed in accordance with embodiments of this specification.The process 1500 can be performed by one or more blockchain nodes or acomputing device communicably coupled to the one or more blockchainnodes. For clarity of presentation, the description that followsgenerally describes process 1500 in the context of the other figures inthis description. However, it will be understood that process 1500 canbe performed, for example, by any system, environment, software, andhardware, or a combination of systems, environments, software, andhardware, as appropriate. In some embodiments, various steps of process1500 can be run in parallel, in combination, in loops, or in any order.

At 1502, a request for collecting a monetary award issued in an order ofa court is received. In some embodiments, the request is associated withan account of a blockchain-based application. In some embodiments, therequest can include an identity associated with the account. Themonetary award can be, for example, cash, funds, stocks, bonds, foreigncurrencies, or other type of asset. In some embodiments, the request canbe initiated by the court or by the creditor.

In some embodiments, the request is a first request, and the account isa first account. Before receiving the first request, a second requestassociated with a second account of the blockchain-based application forrecording the order of the court can be received, where the secondrequest includes an identity associated with the second account. Basedon the trusted identity module, a determination can be made that thesecond account is associated with the court based on the identityassociated with the second account and registration information of thesecond account recorded on the blockchain. The trusted computing modulecan be invoked to record the order on the blockchain as hash value ofthe order. A third verified time stamp can be recorded, by the trustedtiming module, representing a time the order is recorded on theblockchain.

At 1504, a determination is made whether the order is authentic. In someembodiments, the determination can be made, by a trusted identity module(e.g., trusted identity module 312), based on matching with a hash valueassociated with the order recorded on a blockchain.

At 1506, a first verified time stamp representing a time the request isreceived on the blockchain is recorded. In some embodiments, the firstverified time stamp is recorded by a trusted timing module (e.g.,trusted timing module 310).

At 1508, the order is parsed. In some embodiments, the trusted computingmodule (e.g., trusted computing module 314) can be invoked to determine,based on parsing the order, a creditor of the monetary award, a debtorof the monetary award, and an amount of the monetary award.

In some embodiments, the trusted computing module can be invoked todetermine, based on parsing the order, a deadline of enforcing themonetary award, where the trusted computing module is invoked totransfer the amount of the monetary award before the deadline.

At 1510, a determination is made whether the account is associated withthe creditor. In some embodiments, based on the trusted identity module,the determination is made that the account is associated with thecreditor based on the identity and registration information of theaccount recorded on the blockchain.

At 1512, a payment account of the creditor and one or more paymentaccounts of the debtor are identified. In some embodiments, the trustedcomputing module is invoked to identify, based on the registrationinformation, a payment account of the creditor and one or more paymentaccounts of the debtor with an aggregated balance greater than or equalto the amount of the monetary award.

In some embodiments, the trusted computing module can inquire all of thepayment accounts of the debtor, without inquiring the exact balances ofall of the payment accounts of the debtor, to identify the one or morepayment accounts of the debtor with an aggregated balance greater thanor equal to the amount of the monetary award. The trusted computingmodule can inquire a payment account if the balance of the paymentaccount is greater than a certain amount. The financial institutionassociated with the payment account can then reply with a yes or no. Forexample, assuming the monetary award is $20,000, the trusted computingmodule can start by inquiring each payment account of the debtor whetherthe payment account has a balance of $20,000. If more than one paymentaccounts reply yes, a payment account can be randomly selected. If nopayment account replies yes, the trusted computing module can reduce theinquiry balance, for example, inquire whether the payment account has abalance of $10,000. The trusted computing module can keep decreasing theinquiry balance until one or more payment accounts of the debtor with anaggregated balance greater than or equal to the amount of the monetaryaward are identified.

At 1514, the amount of the monetary award is transferred. In someembodiments, the trusted computing module can be invoked to transfer theamount of the monetary award from the one or more payment accounts ofthe debtor to the payment account of the creditor. In some embodiments,the trusted computing module can be invoked to transfer the amount ofthe monetary award based on receiving an alert from a financialinstitution associated with the one or more payment accounts, andwherein the alert indicates that a withdrawal request or a moneytransfer request is initiated from the at least one of the one or morepayment accounts.

In some embodiments, the trusted computing module can be invoked totransfer the amount of the monetary award when the alert indicates thata withdrawal amount or a money transfer amount associated with thewithdrawal request or the money transfer request will make the remainingbalance less than the monetary award. For example, assuming the monetaryaward is $20,000 and the balance of a payment account of the debtor is$30,000, if the withdrawal amount or the money transfer amount is$20,000, the remaining balance of the payment account after thewithdrawal or the money transfer will be $10,000, which is less than themonetary award. An alert can then be triggered to indicate that thewithdrawal amount or the money transfer amount associated with thewithdrawal request or the money transfer request will make the remainingbalance less than the monetary award, and the trusted computing modulecan be invoked to transfer the amount of the monetary award.

In some embodiments, there is a waiting period, e.g., 24 hours, betweenthe time that the withdrawal request or the money transfer request isinitiated and the time that the withdrawal request or the money transferrequest is executed by the financial institution. An alert from thefinancial institution can be sent to the trusted computing module at thetime that the withdrawal request or the money transfer request isinitiated. The trusted computing module can then determine whether totransfer the amount of the monetary award in the waiting period.

At 1516, a second verified time stamp representing a time the amount ofthe monetary award is transferred is recorded. In some embodiments, thesecond verified time stamp can be recorded by the trusted timing module.

Although the present invention is defined in the attached claims, itshould be understood that the present invention can also be defined inaccordance with the following embodiments:

Embodiment 1: A system comprising: an application layer comprising atleast one blockchain-based application program configured to perform aplurality of steps to provide a service; and a trusted service layercomprising a trusted timing module, a trusted identity module, and atrusted computing module; wherein for each step of at least some of theplurality of steps, the application program is configured to perform, atleast one of obtaining a verified time stamp from the trusted timingmodule, obtaining a verified identity from the trusted identity module,or obtaining a computation result based on a processing of blockchaindata using the trusted computing module, and the trusted computingmodule is configured to record information about the corresponding stepthat is performed by the application program and at least one of theverified time stamp, the verified identity, or the computation result ina blockchain.

Embodiment 2: The system of embodiment 1, wherein the trusted computingmodule is configured to, in response to a request for a verified recordassociated with the service, provide the verified record of theplurality of steps performed by the application program and the at leastone of the verified time stamp, the verified identity, or thecomputation result associated with each step of the plurality of steps.

Embodiment 3: The system of embodiment 1 or 2, wherein the trustedcomputing module comprises one or more data processors having a TEE thatis isolated from the one or more data processors' operating system andconfigured to provide enhanced confidentiality and integrity of codeexecuting, and data loaded within, the one or more data processors.

Embodiment 4: The system of embodiment 3, wherein the blockchain basedapplication program comprises a trusted component that is configured tobe executed in the trusted execution environment and record theplurality of steps performed by the application program and the at leastone of the verified time stamp, the verified identity, or thecomputation result associated with each step of the plurality of steps.

Embodiment 5: The system of embodiment 4, wherein the trusted componentcomprises a hash computation component that is configured to generatehash values of data representing the steps performed by the applicationprogram based on a hash algorithm.

Embodiment 6: The system of any of embodiments 1 to 5, wherein theblockchain based application program is configured to invoke functionsof the trusted timing module, the trusted identity module, or thetrusted computing module through a corresponding application programminginterface (API) associated with the trusted timing module, the trustedidentity module, or the trusted computing module.

Embodiment 7: The system of any of embodiments 1 to 6, wherein thetrusted timing module is configured to generate time stamps based on atleast one of (i) national standard timing information, or (ii) timinginformation obtained from a global positioning system.

Embodiment 8: The system of any of embodiments 1 to 7, wherein thetrusted timing module is configured to generate time stamps associatedwith a first user using a first standard time recognized by a firstcourt system associated with the first user, and to generate time stampsassociated with a second user using a second standard time recognized bya second court system associated with the second user, in which thefirst and second users reside in different regions having differentcourt systems.

Embodiment 9: The system of any of embodiments 1 to 8, wherein thetrusted identity module is configured to verify an identity of a userbased on one or more of identifiers associated with the user, theidentifiers including at least one of (i) a mobile phone number, (ii) acredit card number, (iii) a user ID associated with an online paymentsystem, (iv) a user ID associated with an online shopping account, (v) auser ID associated with a music streaming or downloading account, (vi) auser IDS associated with a movie streaming or downloading account, (vii)a user ID associated with a messaging or chat account, (viii) a user IDassociated with an online banking account, (ix) a user ID associatedwith a ride hailing service, (x) a user ID associated with an onlinefood ordering service, (xi) a social security number, (xii) a driver'slicense number, (xiii) a passport number, (xiv) a user ID associatedwith an online gaming service, (xv) an ID issued by a government entity,(xvi) one or more fingerprints, (xvii) one or more voice prints, or(xviii) iris information.

Embodiment 10: The system of any of embodiments 1 to 9, wherein thetrusted identity module is configured to verify the identity of a firstuser using at least one of a first set of identifiers recognized by afirst court system associated with the first user, and to verify theidentity of a second user using at least one of a second set ofidentifiers recognized by a second court system associated with thesecond user, in which the first and second users reside in differentregions having different court systems.

Embodiment 11: The system of any of embodiments 1 to 10, wherein thetrusted computing module is configured to record information associatedwith the user in compliance with privacy laws.

Embodiment 12: The system of any of embodiments 1 to 11, wherein theblockchain based application program provides a shopping service toenable the user to search for information about a product provided by aseller and place an order for the product, wherein the applicationprogram is configured to invoke the trusted identity module to verify anidentity of the user and an identity of the seller, and invoke thetrusted timing module to verify a timing of placement of the order bythe user.

Embodiment 13: The system of embodiment 12, wherein the blockchain basedapplication program is configured to invoke the trusted computing moduleto update the blockchain, and the blockchain is configured to includedata representing online activities of the user associated with theplacement of the order of the product.

Embodiment 14: The system of embodiment 13, wherein the blockchain basedapplication program is configured to invoke the trusted computing moduleto update the blockchain to include data representing information shownto the user and each piece of information provided by the user to theseller after the user initiates a checkout process, an identity of theuser, an identity of the seller, and a timing of the placement of theorder.

Embodiment 15: The system of embodiment 14, wherein the informationshown to the user after the user initiates the checkout process includesa description of the product that is being ordered, a price of theproduct, an identifier of the seller, a name of an entity to receive theproduct, a shipping address, and a message asking the user to confirmplacement of the order.

Embodiment 16: The system of any of embodiments 1 to 15, wherein theblockchain based application program comprises a web browser configuredto enable the user to view web pages on a network and save contents ofone or more of the web pages in a storage, wherein the applicationprogram is configured to invoke the trusted identity module to verify anidentity of the user, and invoke the trusted timing module to verify atiming that a web page has been viewed and/or saved by the user.

Embodiment 17: The system of embodiment 16, wherein the blockchain basedapplication program is configured to invoke the trusted computing moduleto update the blockchain, and the blockchain is configured to includedata representing contents of web pages viewed and/or saved by the user,URLs of the web pages, an identity of the user, and time stamps showingwhen the web pages were viewed and/or saved by the user.

Embodiment 18: The system of any of embodiments 1 to 17, wherein theblockchain based application program provides an online agreementsigning service to enable two or more parties to enter into an agreementonline, wherein the application program is configured to invoke thetrusted identity module to verify identities of parties to theagreement, and invoke the trusted timing module to verify a timing ofsigning the agreement by each of the parties.

Embodiment 19: The system of embodiment 18, wherein the blockchain basedapplication program invokes the trusted computing module to update theblockchain, and the blockchain is configured to include datarepresenting online activities of the parties associated with thesigning of the agreement.

Embodiment 20: The system of embodiment 18, wherein the blockchain basedapplication program invokes the trusted computing module to update theblockchain to include data representing (i) contents of the agreementsigned by each party, (ii) modifications, if any, made to the agreementby each party, (iii) identity of each party signing the agreement, and(iv) time stamps shown when the agreement was signed by each party.

Embodiment 21: A method comprising: at a blockchain-based trustedplatform, providing a service to a user in a plurality of steps; foreach step of the plurality of steps, performing at least one ofobtaining a verified time stamp from a trusted timing module of thetrusted platform, obtaining a verified identity from a trusted identitymodule of the trusted platform, or obtaining a computation result from atrusted computing module of the trusted platform, and recording dataassociated with the service provided to the user and at least one of theverified time stamp, the verified identity, or the computation resultassociated with the step in a blockchain.

Embodiment 22: The method of embodiment 21, comprising in response to arequest for a verified record associated with the service, providing theverified record of the plurality of steps performed by an applicationprogram and the at least one of the verified time stamp, the verifiedidentity, or the computation result associated with each step of theplurality of steps.

Embodiment 23: The method of embodiment 21 or 22, comprising using thetrusted computing module to process blockchain data of the blockchainusing one or more data processors having a TEE that is isolated from theone or more data processors' operating system and configured to provideenhanced confidentiality and integrity of code executing, and dataloaded within, the one or more data processors.

Embodiment 24: The method of embodiment 23, comprising executing atrusted component associated with provisioning of the service in thetrusted execution environment and recording the plurality of steps ofthe service provided to the user and the at least one of the verifiedtime stamp, the verified identity, or the computation result associatedwith each step of the plurality of steps in the blockchain.

Embodiment 25: The method of embodiment 24, wherein executing thetrusted component comprises calculating hash values of data associatedwith the steps of the services provided to the user based on a hashalgorithm.

Embodiment 26: The method of any of embodiments 1 to 25, comprising, ata blockchain based application program of the trusted platformconfigured to provide the service to the user, invoking functions of thetrusted timing module, the trusted identity module, or the trustedcomputing module through a corresponding application programminginterface (API) associated with the trusted timing module, the trustedidentity module, or the trusted computing module.

Embodiment 27: The method of any of embodiments 21 to 26, comprising atthe trusted timing module, generating time stamps based on at least oneof (i) national standard timing information, or (ii) timing informationobtained from a global positioning system.

Embodiment 28: The method of any of embodiments 21 to 27, comprising atthe trusted timing module, generating time stamps associated with afirst user using a first standard time recognized by a first courtsystem associated with the first user, and generating time stampsassociated with a second user using a second standard time recognized bya second court system associated with the second user, in which thefirst and second users reside in different regions having differentcourt systems.

Embodiment 29: The method of any of embodiments 21 to 28, comprising atthe trusted identity module, verifying an identity of a user based onone or more of identifiers associated with the user, the identifiersincluding at least one of (i) a mobile phone number, (ii) a credit cardnumber, (iii) a user ID associated with an online payment system, (iv) auser ID associated with an online shopping account, (v) a user IDassociated with a music streaming or downloading account, (vi) a userIDS associated with a movie streaming or downloading account, (vii) auser ID associated with a messaging or chat account, (viii) a user IDassociated with an online banking account, (ix) a user ID associatedwith a ride hailing service, (x) a user ID associated with an onlinefood ordering service, (xi) a social security number, (xii) a driver'slicense number, (xiii) a passport number, (xiv) a user ID associatedwith an online gaming service, (xv) an ID issued by a government entity,(xvi) one or more fingerprints, (xvii) one or more voice prints, or(xviii) iris information.

Embodiment 30: The method of any of embodiments 21 to 29, comprising atthe trusted identity module, verifying the identity of a first userusing at least one of a first set of identifiers recognized by a firstcourt system associated with the first user, and verifying the identityof a second user using at least one of a second set of identifiersrecognized by a second court system associated with the second user, inwhich the first and second users reside in different regions havingdifferent court systems.

Embodiment 31: The method of any of embodiments 21 to 30, comprising atthe trusted computing module, recording information associated with theuser in compliance with privacy laws.

Embodiment 32: The method of any of embodiments 21 to 31, whereinproviding the service comprises providing a shopping service to enablethe user to search for information about a product provided by a sellerand place an order for the product, and the method comprises invokingthe trusted identity module to verify an identity of the user and anidentity of the seller, and invoking the trusted timing module to verifya timing of placement of the order by the user.

Embodiment 33: The method of embodiment 32, comprising invoking thetrusted computing module to update the blockchain, in which theblockchain is configured to include data representing online activitiesof the user associated with the placement of the order of the product.

Embodiment 34: The method of embodiment 33, comprising invoking thetrusted computing module to update the blockchain to include datarepresenting information shown to the user and each piece of informationprovided by the user to the seller after the user initiates a checkoutprocess, an identity of the user, an identity of the seller, and atiming of the placement of the order.

Embodiment 35: The method of embodiment 34, wherein the informationshown to the user after the user initiates the checkout process includesa description of the product that is being ordered, a price of theproduct, an identifier of the seller, a name of an entity to receive theproduct, a shipping address, and a message asking the user to confirmplacement of the order.

Embodiment 36: The method of any of embodiments 21 to 35, whereinproviding the service comprises providing a web browser configured toenable the user to view web pages on a network and save contents of oneor more of the web pages in a storage, and the method comprises invokingthe trusted identity module to verify an identity of the user, andinvoking the trusted timing module to verify a timing that a web pagehas been viewed and/or saved by the user.

Embodiment 37: The method of embodiment 36, comprising invoking thetrusted computing module to update the blockchain, in which theblockchain is configured to include data representing contents of webpages viewed and/or saved by the user, URLs of the web pages, anidentity of the user, and time stamps showing when the web pages wereviewed and/or saved by the user.

Embodiment 38: The method of any of embodiments 21 to 37, whereinproviding the service comprises providing an online agreement signingservice to enable two or more parties to enter into an agreement online,and the method comprises invoking the trusted identity module to verifyidentities of parties to the agreement, and invoking the trusted timingmodule to verify a timing of signing the agreement by each of theparties.

Embodiment 39: The method of embodiment 38, wherein the blockchain basedapplication program invokes the trusted computing module to update theblockchain, in which the blockchain is configured to include datarepresenting online activities of the parties associated with thesigning of the agreement.

Embodiment 40: The method of embodiment 38 or 39, comprising invokingthe trusted computing module to update the blockchain to include datarepresenting (i) contents of the agreement signed by each party, (ii)modifications, if any, made to the agreement by each party, (iii)identity of each party signing the agreement, and (iv) time stamps shownwhen the agreement was signed by each party.

FIG. 16 is a flowchart illustrating an example of a process 1600 thatcan be executed in accordance with embodiments of this specification.The process 1600 can be performed by one or more blockchain nodes or acomputing device communicably coupled to the one or more blockchainnodes. For clarity of presentation, the description that followsgenerally describes process 1600 in the context of the other figures inthis description. However, it will be understood that process 1600 canbe performed, for example, by any system, environment, software, andhardware, or a combination of systems, environments, software, andhardware, as appropriate. In some embodiments, various steps of process1600 can be run in parallel, in combination, in loops, or in any order.

At 1602, at a blockchain-based trusted platform, a service is providedto a user in a plurality of steps. In some embodiments, the serviceincludes serving notice to another user. In some embodiments, theservice includes providing potential dispute resolutions to two or moreusers having a dispute. In some embodiments, the service includesproviding legal documentation. In some embodiments, the service includesexecution of court ordered judgements.

At 1604, for each step of the plurality of steps, at least one ofobtaining a verified time stamp from a trusted timing module of thetrusted platform, obtaining a verified identity from a trusted identitymodule of the trusted platform, or obtaining a computation result from atrusted computing module of the trusted platform is performed.

In some embodiments, the trusted computing module is used to processblockchain data of the blockchain using one or more data processorshaving a TEE that is isolated from the one or more data processors'operating system and configured to provide enhanced confidentiality andintegrity of code executing, and data loaded within, the one or moredata processors. In some embodiments, a trusted component associatedwith provisioning of the service is executed in the trusted executionenvironment, and the plurality of steps of the service provided to theuser and the at least one of the verified time stamp, the verifiedidentity, or the computation result associated with each step of theplurality of steps are recorded in the blockchain. In some embodiments,executing the trusted component includes calculating hash values of dataassociated with the steps of the services provided to the user based ona hash algorithm.

In some embodiments, at a blockchain based application program of thetrusted platform configured to provide the service to the user,functions of the trusted timing module, the trusted identity module, orthe trusted computing module are invoked through a corresponding APIassociated with the trusted timing module, the trusted identity module,or the trusted computing module.

In some embodiments, the trusted timing module generates time stampsbased on at least one of (i) national standard timing information, or(ii) timing information obtained from a global positioning system. Insome embodiments, the trusted timing module generates time stampsassociated with a first user using a first standard time recognized by afirst court system associated with the first user, and generates timestamps associated with a second user using a second standard timerecognized by a second court system associated with the second user, inwhich the first and second users reside in different regions havingdifferent court systems.

In some embodiments, the trusted identity module verifies an identity ofa user based on one or more of identifiers associated with the user, inwhich the identifiers include at least one of (i) a mobile phone number,(ii) a credit card number, (iii) a user ID associated with an onlinepayment system, (iv) a user ID associated with an online shoppingaccount, (v) a user ID associated with a music streaming or downloadingaccount, (vi) a user IDS associated with a movie streaming ordownloading account, (vii) a user ID associated with a messaging or chataccount, (viii) a user ID associated with an online banking account,(ix) a user ID associated with a ride hailing service, (x) a user IDassociated with an online food ordering service, (xi) a social securitynumber, (xii) a driver's license number, (xiii) a passport number, (xiv)a user ID associated with an online gaming service, (xv) an ID issued bya government entity, (xvi) one or more fingerprints, (xvii) one or morevoice prints, or (xviii) iris information. In some embodiments, thetrusted identity module verifies the identity of a first user using atleast one of a first set of identifiers recognized by a first courtsystem associated with the first user, and verifies the identity of asecond user using at least one of a second set of identifiers recognizedby a second court system associated with the second user, in which thefirst and second users reside in different regions having differentcourt systems.

In some embodiments, the trusted computing module records informationassociated with the user in compliance with privacy laws.

At 1606, data associated with the service provided to the user and atleast one of the verified time stamp, the verified identity, or thecomputation result associated with the step is recorded in a blockchain.

The process 1600 includes, optionally, in response to a request for averified record associated with the service, providing the verifiedrecord of the plurality of steps performed by the application programand the at least one of the verified time stamp, the verified identity,or the computation result associated with each step of the plurality ofsteps.

In some embodiments, providing the service includes providing a shoppingservice to enable the user to search for information about a productprovided by a seller and place an order for the product, the trustedidentity module is invoked to verify an identity of the user and anidentity of the seller, and the trusted timing module is invoked toverify a timing of placement of the order by the user. In someembodiments, the trusted computing module is invoked to update theblockchain, and the blockchain is configured to include datarepresenting online activities of the user associated with the placementof the order of the product. In some embodiments, the trusted computingmodule is invoked to update the blockchain to include data representinginformation shown to the user and each piece of information provided bythe user to the seller after the user initiates a checkout process, anidentity of the user, an identity of the seller, and a timing of theplacement of the order. In some embodiments, the information shown tothe user after the user initiates the checkout process includes adescription of the product that is being ordered, a price of theproduct, an identifier of the seller, a name of an entity to receive theproduct, a shipping address, and a message asking the user to confirmplacement of the order.

In some embodiments, providing the service includes providing a webbrowser configured to enable the user to view web pages on a network andsave contents of one or more of the web pages in a storage, the trustedidentity module is invoked to verify an identity of the user, and thetrusted timing module is invoked to verify a timing that a web page hasbeen viewed and/or saved by the user. In some embodiments, the trustedcomputing module is invoked to update the blockchain, in which theblockchain is configured to include data representing contents of webpages viewed and/or saved by the user, URLs of the web pages, anidentity of the user, and time stamps showing when the web pages wereviewed and/or saved by the user.

In some embodiments, providing the service includes providing an onlineagreement signing service to enable two or more parties to enter into anagreement online, the trusted identity module is invoked to verifyidentities of parties to the agreement, and the trusted timing module isinvoked to verify a timing of signing the agreement by each of theparties. In some embodiments, the blockchain based application programinvokes the trusted computing module to update the blockchain, in whichthe blockchain is configured to include data representing onlineactivities of the parties associated with the signing of the agreement.In some embodiments, the trusted computing module is invoked to updatethe blockchain to include data representing (i) contents of theagreement signed by each party, (ii) modifications, if any, made to theagreement by each party, (iii) identity of each party signing theagreement, and (iv) time stamps shown when the agreement was signed byeach party.

FIG. 17 is a diagram of an example of modules of an apparatus 1700 inaccordance with embodiments of this specification. The apparatus 1700can be an example of an embodiment of a blockchain-based trustedplatform configured to provide a legal service to a user. The apparatus1700 can correspond to the embodiments described above, and theapparatus 1700 includes the following: a providing module 1702 thatprovides a service to a user in a plurality of steps, a trusted timingmodule 1704 that provides a verified time stamp, a trusted identitymodule 1706 that provides a verified identity, a trusted computingmodule 1708 that provides a trusted computation result, and a recordingmodule 1710 that records data associated with the service provided tothe user and at least one of the verified time stamp, the verifiedidentity, or the computation result associated with the step in ablockchain.

In an optional embodiment, the providing module 1702 includes ablockchain-based trusted platform, such as a blockchain-based trustedonline platform.

In an optional embodiment, the apparatus 1700 further includes aproviding module that, in response to a request for a verified recordassociated with the service, provides the verified record of theplurality of steps performed by an application program and the at leastone of the verified time stamp, the verified identity, or thecomputation result associated with each step of the plurality of steps.

In an optional embodiment, the trusted computing module 1708 processesblockchain data of the blockchain using one or more data processorshaving a TEE that is isolated from the one or more data processors'operating system and configured to provide enhanced confidentiality andintegrity of code executing, and data loaded within, the one or moredata processors.

In an optional embodiment, the trusted computing module 1708 executes atrusted component associated with provisioning of the service in thetrusted execution environment and records the plurality of steps of theservice provided to the user and the at least one of the verified timestamp, the verified identity, or the computation result associated witheach step of the plurality of steps in the blockchain.

In an optional embodiment, the trusted component calculates hash valuesof data associated with the steps of the services provided to the userbased on a hash algorithm.

In an optional embodiment, the blockchain based trusted platformincludes a blockchain-based application program that provides theservice to the user, and the application program invokes functions ofthe trusted timing module 1704, the trusted identity module 1706, or thetrusted computing module 1708 through a corresponding applicationprogramming interface (API) associated with the trusted timing module,the trusted identity module, or the trusted computing module.

In an optional embodiment, the trusted timing module 1704 generates timestamps based on at least one of (i) national standard timinginformation, or (ii) timing information obtained from a globalpositioning system.

In an optional embodiment, the trusted timing module 1704 generates timestamps associated with a first user using a first standard timerecognized by a first court system associated with the first user, andgenerating time stamps associated with a second user using a secondstandard time recognized by a second court system associated with thesecond user, in which the first and second users reside in differentregions having different court systems.

In an optional embodiment, the trusted identity module 1706 verifies anidentity of a user based on one or more of identifiers associated withthe user, in which the identifiers include at least one of (i) a mobilephone number, (ii) a credit card number, (iii) a user ID associated withan online payment system, (iv) a user ID associated with an onlineshopping account, (v) a user ID associated with a music streaming ordownloading account, (vi) a user IDS associated with a movie streamingor downloading account, (vii) a user ID associated with a messaging orchat account, (viii) a user ID associated with an online bankingaccount, (ix) a user ID associated with a ride hailing service, (x) auser ID associated with an online food ordering service, (xi) a socialsecurity number, (xii) a driver's license number, (xiii) a passportnumber, (xiv) a user ID associated with an online gaming service, (xv)an ID issued by a government entity, (xvi) one or more fingerprints,(xvii) one or more voice prints, or (xviii) iris information.

In an optional embodiment, the trusted identity module 1706 verifies theidentity of a first user using at least one of a first set ofidentifiers recognized by a first court system associated with the firstuser, and verifies the identity of a second user using at least one of asecond set of identifiers recognized by a second court system associatedwith the second user, in which the first and second users reside indifferent regions having different court systems.

In an optional embodiment, the trusted computing module 1708 recordsinformation associated with the user in compliance with privacy laws.

In an optional embodiment, the providing module 1702 provides a shoppingservice to enable the user to search for information about a productprovided by a seller and place an order for the product, the trustedidentity module 1706 is invoked to verify an identity of the user and anidentity of the seller, and the trusted timing module 1704 is invoked toverify a timing of placement of the order by the user.

In an optional embodiment, the trusted computing module 1708 is invokedto update the blockchain, in which the blockchain is configured toinclude data representing online activities of the user associated withthe placement of the order of the product.

In an optional embodiment, the trusted computing module 1708 is invokedto update the blockchain to include data representing information shownto the user and each piece of information provided by the user to theseller after the user initiates a checkout process, an identity of theuser, an identity of the seller, and a timing of the placement of theorder.

In an optional embodiment, the information shown to the user after theuser initiates the checkout process includes a description of theproduct that is being ordered, a price of the product, an identifier ofthe seller, a name of an entity to receive the product, a shippingaddress, and a message asking the user to confirm placement of theorder.

In an optional embodiment, the providing module 1702 provides a webbrowser configured to enable the user to view web pages on a network andsave contents of one or more of the web pages in a storage, the trustedidentity module 1706 is invoked to verify an identity of the user, andthe trusted timing module 1704 is invoked to verify a timing that a webpage has been viewed and/or saved by the user.

In an optional embodiment, the trusted computing module 1704 is invokedto update the blockchain, in which the blockchain is configured toinclude data representing contents of web pages viewed and/or saved bythe user, URLs of the web pages, an identity of the user, and timestamps showing when the web pages were viewed and/or saved by the user.

In an optional embodiment, the providing module 1702 provides an onlineagreement signing service to enable two or more parties to enter into anagreement online, the trusted identity module 1706 is invoked to verifyidentities of parties to the agreement, and the trusted timing module1704 is invoked to verify a timing of signing the agreement by each ofthe parties.

In an optional embodiment, the blockchain based application programinvokes the trusted computing module to update the blockchain, in whichthe blockchain is configured to include data representing onlineactivities of the parties associated with the signing of the agreement.

In an optional embodiment, the trusted computing module 1708 is invokedto update the blockchain to include data representing (i) contents ofthe agreement signed by each party, (ii) modifications, if any, made tothe agreement by each party, (iii) identity of each party signing theagreement, and (iv) time stamps shown when the agreement was signed byeach party.

FIG. 18 is a diagram of an example of modules of another apparatus 1800in accordance with embodiments of this specification. The apparatus 1800can be an example of an embodiment of a blockchain node configured toimplement service of process in a blockchain network. The apparatus 1800can correspond to the embodiments described above, and the apparatus1800 includes the following: a receiving module 1802 that receives arequest generated based on a blockchain-based application for deliveringa notice associated with a legal action from a serving party to a partyto be served, wherein the request includes an identity associated withthe serving party and an identity associated with the party to beserved; a first determining module 1804 that determines that the servingparty is a registered user of the blockchain-based application based onmatching the identity of the serving party with an identity included inregistration information of the serving party recorded on a blockchain;a recording module 1806 that records a time that the request is receivedon the blockchain; a second determining module 1808 that determineswhether the party to be served is a registered user of theblockchain-based application based on the identity associated with theparty to be served; an identifying module 1810 that identifies one ormore manners of delivering the notice based on available communicationmethods included in the registration information of the serving partyand registration information of the party to be served in response todetermining that the party to be served is a registered user; and adelivering module 1812 that delivers the notice to the party to beserved based on at least one of the one or more manners.

In an optional embodiment, the apparatus 1800 further includes thefollowing: a sending sub-module that sends a notification to an accountassociated with the serving party in response to determining that theparty to be served is not a registered user of the blockchain-basedapplication.

In an optional embodiment, the apparatus 1800 further includes thefollowing: a determining sub-module that determines whether the party tobe served is logged on to an account registered with theblockchain-based application after delivering the notice to the party tobe served; and a sending sub-module that sends a notification to anaccount associated with the serving party to notify that the notice isdelivered in response to determining that the party to be served islogged on to the account registered with the blockchain-basedapplication.

In an optional embodiment, the apparatus 1800 further includes thefollowing: a sending sub-module that sends a notification to the accountassociated with the serving party to notify that the party to be servedis offline in response to determining that the party to be served is notlogged on to the account registered with the blockchain-basedapplication.

In an optional embodiment, the apparatus 1800 further includes thefollowing: an adding sub-module that adds the time, and a digitalsignature generated based on the time to the notice before deliveringthe notice to the party to be served.

In an optional embodiment, the apparatus 1800 further includes thefollowing: a receiving sub-module that receives, from an accountassociated with the party to be served, an acknowledgement for acceptingthe notice from a serving party; a recording sub-module that records atime the acknowledgement is received on the blockchain; and a deliveringsub-module that delivers the acknowledgement to the serving party basedon the available communication methods included in the registrationinformation of the serving party.

In an optional embodiment, the available communication methods compriseat least one of the following: e-mail, telephone call, or instantmessaging.

Referring again to FIG. 18, it can be interpreted as illustrating aninternal functional module and a structure of a blockchain service ofprocess apparatus. The blockchain service of process apparatus can be anexample of a blockchain node configured to implement service of processin a blockchain network. An execution body in essence can be anelectronic device, and the electronic device includes the following: oneor more processors; and one or more computer-readable memoriesconfigured to store an executable instruction of the one or moreprocessors. In some embodiments, the one or more computer-readablememories are coupled to the one or more processors and have programminginstructions stored thereon that are executable by the one or moreprocessors to perform algorithms, methods, functions, processes, flows,and procedures, as described in this specification.

Described embodiments of the subject matter can include one or morefeatures, alone or in combination. For example, in a first embodiment, amethod for facilitating blockchain-based service of process performed bya blockchain node includes: receiving a request generated based on ablockchain-based application for delivering a notice associated with alegal action from a serving party to a party to be served, wherein therequest comprises an identity associated with the serving party and anidentity associated with the party to be served; determining that theserving party is a registered user of the blockchain-based applicationbased on matching the identity of the serving party with an identityincluded in registration information of the serving party recorded on ablockchain; recording a time that the request is received on theblockchain; determining whether the party to be served is a registereduser of the blockchain-based application based on the identityassociated with the party to be served; in response to determining thatthe party to be served is a registered user, identifying one or moremanners of delivering the notice based on available communicationmethods included in the registration information of the serving partyand registration information of the party to be served; and deliveringthe notice to the party to be served based on at least one of the one ormore manners.

The foregoing and other described embodiments can each, optionally,include one or more of the following features:

A first feature, combinable with any of the following features,specifies that the method further includes: in response to determiningthat the party to be served is not a registered user of theblockchain-based application, sending a notification to an accountassociated with the serving party.

A second feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: determiningwhether the party to be served is logged on to an account registeredwith the blockchain-based application after delivering the notice to theparty to be served; and in response to determining that the party to beserved is logged on to the account registered with the blockchain-basedapplication, sending a notification to an account associated with theserving party to notify that the notice is delivered.

A third feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: in response todetermining that the party to be served is not logged on to the accountregistered with the blockchain-based application, sending a notificationto the account associated with the serving party to notify that theparty to be served is offline.

A fourth feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: adding the time,and a digital signature generated based on the time to the notice beforedelivering the notice to the party to be served.

A fifth feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: receiving, from anaccount associated with the party to be served, an acknowledgement foraccepting the notice from a serving party; recording a time theacknowledgement is received on the blockchain; and delivering theacknowledgement to the serving party based on the availablecommunication methods included in the registration information of theserving party.

A sixth feature, combinable with any of the previous or followingfeatures, specifies that the available communication methods comprise atleast one of the following: e-mail, telephone call, or instantmessaging.

FIG. 19 is a diagram of on example of modules of yet another apparatus1900 in accordance with embodiments of this specification. The apparatus1900 can be an example of an embodiment of a blockchain node configuredto perform a dispute resolution process in a blockchain network. Theapparatus 1900 can correspond to the embodiments described above, andthe apparatus 1900 includes the following: a first receiving module 1902that receives a request for resolving a dispute between at least a firstparty and a second party, wherein the request comprises a first identityassociated with the first party and a second identify associated withthe second party; a first determining module 1904 that determines thatthe first party and the second party are registered users of theblockchain-based application based on matching the first identity withan identity included in registration information of the first partyrecorded on a blockchain and matching the second identity with anidentity included in registration information of the second partyrecorded on the blockchain; a first recording module 1906 that records atime that the request is received on the blockchain; a second receivingmodule 1908 that receives one or more potential dispute solutions fromone or more dispute solution providers that are registered on theblockchain-based application; a third receiving module 1910 thatreceives a first selection from the first party and a second selectionfrom the second party, wherein the first selection comprises a first setof the one or more potential dispute solutions and the second selectioncomprises a second set of the one or more potential dispute solutions; asecond recording module 1912 that records a time that the firstselection is received on the blockchain and a time that the secondselection is received on the blockchain; and a second determining module1914 that determines at least one of (i) at least one common potentialdispute solution between the first set of the one or more potentialdispute solutions and the second set of the one or more potentialdispute solutions, or (ii) that none of the potential dispute solutionsare acceptable to the first and second parties.

In an optional embodiment, the request for resolving the disputecomprises a virtual asset and the apparatus 1900 further includes thefollowing: a sending sub-module that sends the virtual asset to at leastone of the one or more dispute solution providers that provides the atleast one common dispute solution.

In an optional embodiment, the apparatus 1900 further includes thefollowing: a first receiving sub-module that receives a first requestfrom the first party for resolving the dispute, the first requestcomprising a first virtual asset; a second receiving sub-module thatreceives a second request from the second party for resolving thedispute, the second request comprising a second virtual asset; and adetermining sub-module that determines the virtual asset based on one ofthe first virtual asset and the second virtual asset that has a highervalue.

In an optional embodiment, the apparatus 1900 further includes thefollowing: a removing sub-module that removes the virtual asset from afirst account associated with the first party and a second accountassociated with the second party respectively; and a storing sub-modulethat stores the virtual asset removed from the first account and thesecond account on the blockchain.

In an optional embodiment, the apparatus 1900 further includes thefollowing: a first determining sub-module that determines that there isno common dispute solution between the first set of the one or moredispute solutions and the second set of the one or more disputesolutions; a receiving sub-module that receives a dispute solution froma statutory authorization entity that is different from the disputesolution providers; a second determining sub-module that determineswhether the dispute solution matches a dispute solution in the first setof the one or more dispute solutions and the second set of the one ormore dispute solutions; a first sending sub-module that sends thevirtual asset removed from the second account to a dispute solutionprovider that provides the dispute solution in the first set of the oneor more dispute solutions in response to determining that the disputesolution most closely matches a dispute solution in the first set of theone or more dispute solutions; or a second sending sub-module that sendsthe virtual asset removed from the first account to a dispute solutionprovider that provides the dispute solution in the second set of the oneor more dispute solutions in response to determining that the disputesolution most closely matches a dispute solution in the second set ofthe one or more dispute solutions.

In an optional embodiment, the first selection and the second selectionare received from the first party and the second party respectivelywithin a predetermined time window.

Referring again to FIG. 16, it can be interpreted as illustrating aninternal functional module and a structure of a blockchain disputeresolution apparatus. The blockchain dispute resolution apparatus can bean example of a blockchain node configured to perform a disputeresolution process in a blockchain network. An execution body in essencecan be an electronic device, and the electronic device includes thefollowing: one or more processors; and one or more computer-readablememories configured to store an executable instruction of the one ormore processors. In some embodiments, the one or more computer-readablememories are coupled to the one or more processors and have programminginstructions stored thereon that are executable by the one or moreprocessors to perform algorithms, methods, functions, processes, flows,and procedures, as described in this specification.

Described embodiments of the subject matter can include one or morefeatures, alone or in combination. For example, in a first embodiment, amethod for performing for blockchain-based dispute resolution processincludes: at a blockchain-based application, receiving a request forresolving a dispute between at least a first party and a second party,wherein the request comprises a first identity associated with the firstparty and a second identify associated with the second party;determining that the first party and the second party are registeredusers of the blockchain-based application based on matching the firstidentity with an identity included in registration information of thefirst party recorded on a blockchain and matching the second identitywith an identity included in registration information of the secondparty recorded on the blockchain; recording a time that the request isreceived on the blockchain; receiving one or more potential disputesolutions from one or more dispute solution providers that areregistered on the blockchain-based application; receiving a firstselection from the first party and a second selection from the secondparty, wherein the first selection comprises a first set of the one ormore potential dispute solutions and the second selection comprises asecond set of the one or more potential dispute solutions; recording atime that the first selection is received on the blockchain and a timethat the second selection is received on the blockchain; and determiningat least one of (i) at least one common potential dispute solutionbetween the first set of the one or more potential dispute solutions andthe second set of the one or more potential dispute solutions, or (ii)that none of the potential dispute solutions are acceptable to the firstand second parties.

The foregoing and other described embodiments can each, optionally,include one or more of the following features:

A first feature, combinable with any of the following features,specifies that the request for resolving the dispute comprises a virtualasset, and the method comprises sending the virtual asset to at leastone of the one or more dispute solution providers that provides the atleast one common dispute solution.

A second feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: receiving a firstrequest from the first party for resolving the dispute, the firstrequest comprising a first virtual asset; receiving a second requestfrom the second party for resolving the dispute, the second requestcomprising a second virtual asset; and determining the virtual assetbased on one of the first virtual asset and the second virtual assetthat has a higher value.

A third feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: removing thevirtual asset from a first account associated with the first party and asecond account associated with the second party respectively; andstoring the virtual asset removed from the first account and the secondaccount on the blockchain.

A fourth feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: determining thatthere is no common dispute solution between the first set of the one ormore dispute solutions and the second set of the one or more disputesolutions; receiving a dispute solution from a statutory authorizationentity that is different from the dispute solution providers;determining whether the dispute solution matches a dispute solution inthe first set of the one or more dispute solutions and the second set ofthe one or more dispute solutions; in response to determining that thedispute solution most closely matches a dispute solution in the firstset of the one or more dispute solutions, sending the virtual assetremoved from the second account to a dispute solution provider thatprovides the dispute solution in the first set of the one or moredispute solutions; or in response to determining that the disputesolution most closely matches a dispute solution in the second set ofthe one or more dispute solutions, sending the virtual asset removedfrom the first account to a dispute solution provider that provides thedispute solution in the second set of the one or more dispute solutions.

A fifth feature, combinable with any of the previous or followingfeatures, specifies that the first selection and the second selectionare received from the first party and the second party respectivelywithin a predetermined time window.

FIG. 20 is a diagram of on example of modules of yet another apparatus2000 in accordance with embodiments of this specification. The apparatus2000 can be an example of an embodiment of a blockchain node configuredto process information. The apparatus 2000 can correspond to theembodiments described above, and the apparatus 2000 includes thefollowing: a receiving module 2002 that receives a request for providinga service initiated from an account of a user associated with ablockchain-based application, wherein the request comprises an identityassociated with the user; a determining module 2004 that determines thatthe user is a registered user of the blockchain-based application basedon matching the identity with an identity included in registrationinformation of the user associated with the blockchain-based applicationand recorded on a blockchain; an identifying module 2006 that identifiesone or more electronic forms to be filled out and submitted in aplurality of steps for providing the service; a generating module 2008that generates a unique identifier (ID) based on a time that the step isperformed and digital content on the electronic form at the time, ateach step of the plurality of steps; a first recording module 2010 thatrecords the unique ID, the time, and the digital content on theblockchain, at each step of the plurality of steps; an embedding module2012 that embeds the unique ID in the digital content at the time bychanging one or more attributes associated with the digital content tobe representative of the unique ID, wherein the embedding producesinformation-embedded digital content that enables retrieval of the timeand the digital content from the blockchain based on the unique ID, ateach step of the plurality of steps; and a second recording module 2014that records the information-embedded digital content to the blockchain,at each step of the plurality of steps.

In an optional embodiment, the request is a first request, and theapparatus 2000 further includes the following: a receiving sub-modulethat receives a second request for handling the first request initiatedfrom an account of a service provider associated with theblockchain-based application, wherein the second request comprises anidentity associated with the service provider; and a determiningsub-module determines that the service provider is a registered serviceprovider of the blockchain-based application based on matching theidentity associated with the service provider with an identity includedin registration information of the service provider recorded on theblockchain.

In an optional embodiment, the plurality of steps are performed by theuser and the service provider.

In an optional embodiment, at each step of the plurality of stepsperformed by the user, the unique ID is generated based on the time andthe digital content on the electronic form filled in by the user at thetime, and wherein the unique ID is embedded in the digital contentfilled in by the user.

In an optional embodiment, the unique ID is a first unique ID, and theapparatus 2000 further includes the following: a generating sub-modulethat generates a second unique ID based on the time that the step isperformed and digital content on the electronic form filled in by theservice provider at the time, at each step of the plurality of stepsperformed by the service provider, and an embedding sub-module thatembeds the second unique ID in the digital content filled in by theservice provider, at each step of the plurality of steps performed bythe service provider.

In an optional embodiment, a visual difference between the electronicform and the information-embedded digital content is not apparent to anunaided human eye.

In an optional embodiment, the unique ID is generated based on at leastone of a hash function or an asymmetric encryption.

In an optional embodiment, the embedding the unique ID is performedbased on digital watermarking using one or more of a discrete wavelettransform, a discrete cosine transform, a singular value decomposition,a least significant bit, or undetectable steganography.

In an optional embodiment, the one or more attributes associated withthe digital content include one or more of color, size, orientation,shape, and font of the digital content.

In an optional embodiment, the identity includes at least one of (i) amobile phone number, (ii) a credit card number, (iii) a user IDassociated with an online payment system, (iv) a user ID associated withan online shopping account, (v) a user ID associated with a musicstreaming or downloading account, (vi) a user IDS associated with amovie streaming or downloading account, (vii) a user ID associated witha messaging or chat account, (viii) a user ID associated with an onlinebanking account, (ix) a user ID associated with a ride hailing service,(x) a user ID associated with an online food ordering service, (xi) asocial security number, (xii) a driver's license number, (xiii) apassport number, (xiv) a user ID associated with an online gamingservice, or (xi) an ID issued by a government entity.

Referring again to FIG. 20, it can be interpreted as illustrating aninternal functional module and a structure of a blockchain informationprocessing apparatus. The blockchain information processing apparatuscan be an example of a blockchain node configured to implementinformation processing in a blockchain network. An execution body inessence can be an electronic device, and the electronic device includesthe following: one or more processors; and one or more computer-readablememories configured to store an executable instruction of the one ormore processors. In some embodiments, the one or more computer-readablememories are coupled to the one or more processors and have programminginstructions stored thereon that are executable by the one or moreprocessors to perform algorithms, methods, functions, processes, flows,and procedures, as described in this specification.

Described embodiments of the subject matter can include one or morefeatures, alone or in combination. For example, in a first embodiment, amethod for blockchain-based information processing performed by ablockchain node includes: receiving a request for providing a serviceinitiated from an account of a user associated with a blockchain-basedapplication, wherein the request comprises an identity associated withthe user; determining that the user is a registered user of theblockchain-based application based on matching the identity with anidentity included in registration information of the user associatedwith the blockchain-based application and recorded on a blockchain;identifying one or more electronic forms to be filled out and submittedin a plurality of steps for providing the service; at each step of theplurality of steps: generating a unique identifier (ID) based on a timethat the step is performed and digital content on the electronic form atthe time; at each step of the plurality of steps: recording the uniqueID, the time, and the digital content on the blockchain; at each step ofthe plurality of steps: embedding the unique ID in the digital contentat the time by changing one or more attributes associated with thedigital content to be representative of the unique ID, wherein theembedding produces information-embedded digital content that enablesretrieval of the time and the digital content from the blockchain basedon the unique ID; and at each step of the plurality of steps: recordingthe information-embedded digital content to the blockchain.

The foregoing and other described embodiments can each, optionally,include one or more of the following features:

A first feature, combinable with any of the following features,specifies that the request is a first request, and the method furtherincludes: receiving a second request for handling the first requestinitiated from an account of a service provider associated with theblockchain-based application, wherein the second request comprises anidentity associated with the service provider; and determining that theservice provider is a registered service provider of theblockchain-based application based on matching the identity associatedwith the service provider with an identity included in registrationinformation of the service provider recorded on the blockchain.

A second feature, combinable with any of the previous or followingfeatures, specifies that the plurality of steps are performed by theuser and the service provider.

A third feature, combinable with any of the previous or followingfeatures, specifies that at each step of the plurality of stepsperformed by the user, the unique ID is generated based on the time andthe digital content on the electronic form filled in by the user at thetime, and wherein the unique ID is embedded in the digital contentfilled in by the user.

A fourth feature, combinable with any of the previous or followingfeatures, specifies that the unique ID is a first unique ID, and themethod further includes: at each step of the plurality of stepsperformed by the service provider: generating a second unique ID basedon the time that the step is performed and digital content on theelectronic form filled in by the service provider at the time; and ateach step of the plurality of steps performed by the service provider:embedding the second unique ID in the digital content filled in by theservice provider.

A fifth feature, combinable with any of the previous or followingfeatures, specifies that a visual difference between the electronic formand the information-embedded digital content is not apparent to anunaided human eye.

A sixth feature, combinable with any of the previous or followingfeatures, specifies that the unique ID is generated based on at leastone of a hash function or an asymmetric encryption.

A seventh feature, combinable with any of the previous or followingfeatures, specifies that the embedding the unique ID is performed basedon digital watermarking using one or more of a discrete wavelettransform, a discrete cosine transform, a singular value decomposition,a least significant bit, or undetectable steganography.

An eighth feature, combinable with any of the previous or followingfeatures, specifies that the one or more attributes associated with thedigital content include one or more of color, size, orientation, shape,and font of the digital content.

A ninth feature, combinable with any of the previous or followingfeatures, specifies that the identity includes at least one of (i) amobile phone number, (ii) a credit card number, (iii) a user IDassociated with an online payment system, (iv) a user ID associated withan online shopping account, (v) a user ID associated with a musicstreaming or downloading account, (vi) a user IDS associated with amovie streaming or downloading account, (vii) a user ID associated witha messaging or chat account, (viii) a user ID associated with an onlinebanking account, (ix) a user ID associated with a ride hailing service,(x) a user ID associated with an online food ordering service, (xi) asocial security number, (xii) a driver's license number, (xiii) apassport number, (xiv) a user ID associated with an online gamingservice, or (xi) an ID issued by a government entity.

FIG. 21 is a diagram of on example of modules of yet another apparatus2100 in accordance with embodiments of this specification. The apparatus2100 can be an example of an embodiment of a blockchain node configuredto handle court ordered judgements The apparatus 2100 can correspond tothe embodiments described above, and the apparatus 2100 includes thefollowing: a receiving module 2102 that receives a request associatedwith an account of a blockchain-based application for collecting amonetary award issued in an order of a court, wherein the requestcomprises an identity associated with the account; a first determinationmodule 2104 that determines that the order is authentic based onmatching with a hash value associated with the order recorded on ablockchain; a first recording module 2106 that records a first verifiedtime stamp representing a time the request is received on theblockchain; a first invoking module 2108 that invokes the trustedcomputing module to determine, based on parsing the order, a creditor ofthe monetary award, a debtor of the monetary award, and an amount of themonetary award; a second determining module 2110 that determines, basedon the trusted identity module, that the account is associated with thecreditor based on the identity and registration information of theaccount recorded on the blockchain; a second invoking module 2112 thatinvokes the trusted computing module to identify, based on theregistration information, a payment account of the creditor and one ormore payment accounts of the debtor with an aggregated balance greaterthan or equal to the amount of the monetary award; a third invokingmodule 2114 that invokes the trusted computing module to transfer theamount of the monetary award from the one or more payment accounts ofthe debtor to the payment account of the creditor; and a secondrecording module 2116 that records a second verified time stamprepresenting a time the amount of the monetary award is transferred.

In an optional embodiment, the apparatus 2100 further includes thefollowing: a receiving sub-module that receives a second requestassociated with a second account of the blockchain-based application forrecording the order of the court, wherein the second request comprisesan identity associated with the second account, before receiving thefirst request, a determining sub-module that determines, based on thetrusted identity module, that the second account is associated with thecourt based on the identity associated with the second account andregistration information of the second account recorded on theblockchain, an invoking sub-module that invokes the trusted computingmodule to record the order on the blockchain as hash value of the order,and a recording sub-module that records a third verified time stamprepresenting a time the order is recorded on the blockchain.

In an optional embodiment, the apparatus 2100 further includes thefollowing: an invoking sub-module that invokes the trusted computingmodule to seize an aggregated monetary amount equal to the amount of themonetary award from the one or more payment accounts.

In an optional embodiment, the apparatus 2100 further includes thefollowing: an invoking sub-module that invokes the trusted computingmodule to determine, based on parsing the order, a deadline of enforcingthe monetary award, wherein the trusted computing module is invoked totransfer the amount of the monetary award before the deadline.

In an optional embodiment, the trusted computing module is invoked totransfer the amount of the monetary award based on receiving an alertfrom a financial institution associated with the one or more paymentaccounts, and wherein the alert indicates that a withdrawal request or amoney transfer request is initiated from the at least one of the one ormore payment accounts.

Referring again to FIG. 21, it can be interpreted as illustrating aninternal functional module and a structure of a blockchain judgementexecution apparatus. The blockchain judgement execution apparatus can bean example of a blockchain node configured to implement judgementexecution in a blockchain network. An execution body in essence can bean electronic device, and the electronic device includes the following:one or more processors; and one or more computer-readable memoriesconfigured to store an executable instruction of the one or moreprocessors. In some embodiments, the one or more computer-readablememories are coupled to the one or more processors and have programminginstructions stored thereon that are executable by the one or moreprocessors to perform algorithms, methods, functions, processes, flows,and procedures, as described in this specification.

Described embodiments of the subject matter can include one or morefeatures, alone or in combination. For example, in a first embodiment, amethod for handling court ordered judgements performed by a blockchainnode includes: receiving a request associated with an account of ablockchain-based application for collecting a monetary award issued inan order of a court, wherein the request comprises an identityassociated with the account; determining, by a trusted identity module,that the order is authentic based on matching with a hash valueassociated with the order recorded on a blockchain; recording, by atrusted timing module, a first verified time stamp representing a timethe request is received on the blockchain; invoking the trustedcomputing module to determine, based on parsing the order, a creditor ofthe monetary award, a debtor of the monetary award, and an amount of themonetary award; determining, based on the trusted identity module, thatthe account is associated with the creditor based on the identity andregistration information of the account recorded on the blockchain;invoking the trusted computing module to identify, based on theregistration information, a payment account of the creditor and one ormore payment accounts of the debtor with an aggregated balance greaterthan or equal to the amount of the monetary award; invoking the trustedcomputing module to transfer the amount of the monetary award from theone or more payment accounts of the debtor to the payment account of thecreditor; and recording, by the trusted timing module, a second verifiedtime stamp representing a time the amount of the monetary award istransferred.

The foregoing and other described embodiments can each, optionally,include one or more of the following features:

A first feature, combinable with any of the following features,specifies that the request is a first request, the account is a firstaccount, and the method further includes: before receiving the firstrequest, receiving a second request associated with a second account ofthe blockchain-based application for recording the order of the court,wherein the second request comprises an identity associated with thesecond account; determining, based on the trusted identity module, thatthe second account is associated with the court based on the identityassociated with the second account and registration information of thesecond account recorded on the blockchain; invoking the trustedcomputing module to record the order on the blockchain as hash value ofthe order; and recording, by the trusted timing module, a third verifiedtime stamp representing a time the order is recorded on the blockchain.

A second feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: invoking thetrusted computing module to seize an aggregated monetary amount equal tothe amount of the monetary award from the one or more payment accounts.

A third feature, combinable with any of the previous or followingfeatures, specifies that the method further includes: invoking thetrusted computing module to determine, based on parsing the order, adeadline of enforcing the monetary award, wherein the trusted computingmodule is invoked to transfer the amount of the monetary award beforethe deadline.

A fourth feature, combinable with any of the previous or followingfeatures, specifies that the trusted computing module is invoked totransfer the amount of the monetary award based on receiving an alertfrom a financial institution associated with the one or more paymentaccounts, and wherein the alert indicates that a withdrawal request or amoney transfer request is initiated from the at least one of the one ormore payment accounts.

The system, apparatus, module, or unit illustrated in the previousembodiments can be implemented by using a computer chip or an entity, orcan be implemented by using a product having a certain function. Atypical embodiment device is a computer, and the computer can be apersonal computer, a laptop computer, a cellular phone, a camera phone,a smartphone, a personal digital assistant, a media player, a navigationdevice, an email receiving and sending device, a game console, a tabletcomputer, a wearable device, or any combination of these devices.

For an embodiment process of functions and roles of each module in theapparatus, references can be made to an embodiment process ofcorresponding steps in the previous method. Details are omitted here forsimplicity.

Because an apparatus embodiment basically corresponds to a methodembodiment, for related parts, references can be made to relateddescriptions in the method embodiment. The previously describedapparatus embodiment is merely an example. The modules described asseparate parts may or may not be physically separate, and partsdisplayed as modules may or may not be physical modules, may be locatedin one position, or may be distributed on a number of network modules.Some or all of the modules can be selected based on actual demands toachieve the objectives of the solutions of the specification. A personof ordinary skill in the art can understand and implement theembodiments of the present application without creative efforts.

Embodiments of the subject matter and the actions and operationsdescribed in this specification can be implemented in digital electroniccircuitry, in tangibly-embodied computer software or firmware, incomputer hardware, including the structures disclosed in thisspecification and their structural equivalents, or in combinations ofone or more of them. Embodiments of the subject matter described in thisspecification can be implemented as one or more computer programs, e.g.,one or more modules of computer program instructions, encoded on acomputer program carrier, for execution by, or to control the operationof, data processing apparatus. For example, a computer program carriercan include one or more computer-readable storage media that haveinstructions encoded or stored thereon. The carrier may be a tangiblenon-transitory computer-readable medium, such as a magnetic, magnetooptical, or optical disk, a solid state drive, a random access memory(RAM), a read-only memory (ROM), or other types of media. Alternatively,or in addition, the carrier may be an artificially generated propagatedsignal, e.g., a machine-generated electrical, optical, orelectromagnetic signal that is generated to encode information fortransmission to suitable receiver apparatus for execution by a dataprocessing apparatus. The computer storage medium can be or be part of amachine-readable storage device, a machine-readable storage substrate, arandom or serial access memory device, or a combination of one or moreof them. A computer storage medium is not a propagated signal.

A computer program, which may also be referred to or described as aprogram, software, a software application, an app, a module, a softwaremodule, an engine, a script, or code, can be written in any form ofprogramming language, including compiled or interpreted languages, ordeclarative or procedural languages; and it can be deployed in any form,including as a stand-alone program or as a module, component, engine,subroutine, or other unit suitable for executing in a computingenvironment, which environment may include one or more computersinterconnected by a data communication network in one or more locations.

A computer program may, but need not, correspond to a file in a filesystem. A computer program can be stored in a portion of a file thatholds other programs or data, e.g., one or more scripts stored in amarkup language document, in a single file dedicated to the program inquestion, or in multiple coordinated files, e.g., files that store oneor more modules, sub programs, or portions of code.

Processors for execution of a computer program include, by way ofexample, both general- and special-purpose microprocessors, and any oneor more processors of any kind of digital computer. Generally, aprocessor will receive the instructions of the computer program forexecution as well as data from a non-transitory computer-readable mediumcoupled to the processor.

The term “data processing apparatus” encompasses all kinds ofapparatuses, devices, and machines for processing data, including by wayof example a programmable processor, a computer, or multiple processorsor computers. Data processing apparatus can include special-purposelogic circuitry, e.g., an FPGA (field programmable gate array), an ASIC(application specific integrated circuit), or a GPU (graphics processingunit). The apparatus can also include, in addition to hardware, codethat creates an execution environment for computer programs, e.g., codethat constitutes processor firmware, a protocol stack, a databasemanagement system, an operating system, or a combination of one or moreof them.

The processes and logic flows described in this specification can beperformed by one or more computers or processors executing one or morecomputer programs to perform operations by operating on input data andgenerating output. The processes and logic flows can also be performedby special-purpose logic circuitry, e.g., an FPGA, an ASIC, or a GPU, orby a combination of special-purpose logic circuitry and one or moreprogrammed computers.

Computers suitable for the execution of a computer program can be basedon general or special-purpose microprocessors or both, or any other kindof central processing unit. Generally, a central processing unit willreceive instructions and data from a read only memory or a random accessmemory or both. Elements of a computer can include a central processingunit for executing instructions and one or more memory devices forstoring instructions and data. The central processing unit and thememory can be supplemented by, or incorporated in, special-purpose logiccircuitry.

Generally, a computer will also include, or be operatively coupled toreceive data from or transfer data to one or more storage devices. Thestorage devices can be, for example, magnetic, magneto optical, oroptical disks, solid state drives, or any other type of non-transitory,computer-readable media. However, a computer need not have such devices.Thus, a computer may be coupled to one or more storage devices, such as,one or more memories, that are local and/or remote. For example, acomputer can include one or more local memories that are integralcomponents of the computer, or the computer can be coupled to one ormore remote memories that are in a cloud network. Moreover, a computercan be embedded in another device, e.g., a mobile telephone, a personaldigital assistant (PDA), a mobile audio or video player, a game console,a Global Positioning System (GPS) receiver, or a portable storagedevice, e.g., a universal serial bus (USB) flash drive, to name just afew.

Components can be “coupled to” each other by being commutatively such aselectrically or optically connected to one another, either directly orvia one or more intermediate components. Components can also be “coupledto” each other if one of the components is integrated into the other.For example, a storage component that is integrated into a processor(e.g., an L2 cache component) is “coupled to” the processor.

To provide for interaction with a user, embodiments of the subjectmatter described in this specification can be implemented on, orconfigured to communicate with, a computer having a display device,e.g., a LCD (liquid crystal display) monitor, for displaying informationto the user, and an input device by which the user can provide input tothe computer, e.g., a keyboard and a pointing device, e.g., a mouse, atrackball or touchpad. Other kinds of devices can be used to provide forinteraction with a user as well; for example, feedback provided to theuser can be any form of sensory feedback, e.g., visual feedback,auditory feedback, or tactile feedback; and input from the user can bereceived in any form, including acoustic, speech, or tactile input. Inaddition, a computer can interact with a user by sending documents toand receiving documents from a device that is used by the user; forexample, by sending web pages to a web browser on a user's device inresponse to requests received from the web browser, or by interactingwith an app running on a user device, e.g., a smartphone or electronictablet. Also, a computer can interact with a user by sending textmessages or other forms of message to a personal device, e.g., asmartphone that is running a messaging application, and receivingresponsive messages from the user in return.

This specification uses the term “configured to” in connection withsystems, apparatus, and computer program components. For a system of oneor more computers to be configured to perform particular operations oractions means that the system has installed on it software, firmware,hardware, or a combination of them that in operation cause the system toperform the operations or actions. For one or more computer programs tobe configured to perform particular operations or actions means that theone or more programs include instructions that, when executed by dataprocessing apparatus, cause the apparatus to perform the operations oractions. For special-purpose logic circuitry to be configured to performparticular operations or actions means that the circuitry has electroniclogic that performs the operations or actions.

While this specification contains many specific embodiment details,these should not be construed as limitations on the scope of what isbeing claimed, which is defined by the claims themselves, but rather asdescriptions of features that may be specific to particular embodiments.Certain features that are described in this specification in the contextof separate embodiments can also be realized in combination in a singleembodiment. Conversely, various features that are described in thecontext of a single embodiments can also be realized in multipleembodiments separately or in any suitable subcombination. Moreover,although features may be described above as acting in certaincombinations and even initially be claimed as such, one or more featuresfrom a claimed combination can in some cases be excised from thecombination, and the claim may be directed to a subcombination orvariation of a subcombination.

Similarly, while operations are depicted in the drawings and recited inthe claims in a particular order, this should not be understood asrequiring that such operations be performed in the particular ordershown or in sequential order, or that all illustrated operations beperformed, to achieve desirable results. In certain circumstances,multitasking and parallel processing may be advantageous. Moreover, theseparation of various system modules and components in the embodimentsdescribed above should not be understood as requiring such separation inall embodiments, and it should be understood that the described programcomponents and systems can generally be integrated together in a singlesoftware product or packaged into multiple software products.

Particular embodiments of the subject matter have been described. Otherembodiments are within the scope of the following claims. For example,the actions recited in the claims can be performed in a different orderand still achieve desirable results. As one example, the processesdepicted in the accompanying figures do not necessarily require theparticular order shown, or sequential order, to achieve desirableresults. In some cases, multitasking and parallel processing may beadvantageous.

What is claimed is:
 1. A computer-implemented method performed by ablockchain node for handling court-ordered judgements, the methodcomprising: receiving a court-ordered judgement that specifies a debtor,a creditor, and an amount of debt owed by the debtor to the creditor;determining that the court-ordered judgement is authentic based onmatching with a hash value associated with the court-ordered judgementrecorded on a blockchain; determining a deadline of enforcing thecourt-ordered judgement; identifying one or more payment accountsassociated with the debtor; receiving an alert from a financialinstitution associated with the one or more payment accounts, whereinthe alert is triggered by a withdrawal request associated with aparticular payment account of the one or more payment accounts, andwherein the alert indicates that, after withdrawing a particular amountof the withdrawal request, a remaining balance of the particular paymentaccount is less than the amount of debt; collecting, as a collectedasset, at least a portion of the amount of debt from the one or morepayment accounts associated with the debtor, before the deadline ofenforcing the court-ordered judgement; sending the collected asset tothe creditor; and adding a record to the blockchain, wherein the recordincludes an amount of the collected asset.
 2. The computer-implementedmethod of claim 1, wherein identifying the one or more payment accountsassociated with the debtor comprises: identifying at least one availablepayment account associated with the debtor; sending at least one firstrequest to at least one financial institution associated with the atleast one available payment account, wherein each first request of theat least one first request is used to determine whether a correspondingavailable payment account of the at least one available payment accounthas a balance that is greater than or equal to the amount of debt; andreceiving at least one first response from the at least one financialinstitution, wherein each first response of the at least one firstresponse indicates either: (i) a balance of a corresponding availablepayment account is greater than or equal to the amount of debt, or (ii)the balance of the corresponding available payment account is less thanthe amount of debt.
 3. The computer-implemented method of claim 2,further comprising: determining that at least two payment accounts eachhas a balance that is greater than or equal to the amount of debtrespectively; and randomly selecting, as the one or more paymentaccounts, a payment account of the at least two payment accounts.
 4. Thecomputer-implemented method of claim 2, further comprising: determiningthat none of the at least one available payment account has a balancethat is greater than or equal to the amount of debt; sending at leastone second request to the at least one financial institution, whereineach second request of the at least one second request is used todetermine whether a corresponding available payment account of the atleast one available payment account has a balance that is greater thanor equal to a particular amount that is less than the amount of debt;receiving at least one second response from the at least one financialinstitution, wherein each second response of the at least one secondresponse indicates either: (i) a balance of a corresponding availablepayment account is greater than or equal to the particular amount, or(ii) the balance of the corresponding available payment account is lessthan the particular amount; and determining, based on the at least onesecond response, the one or more payment accounts having an aggregatedbalance greater than or equal to the amount of debt.
 5. Thecomputer-implemented method of claim 4, further comprising: decreasingthe particular amount until the one or more payment accounts having theaggregated balance greater than or equal to the amount of debt areidentified.
 6. The computer-implemented method of claim 1, furthercomprising, before receiving the court-ordered judgement: receiving arequest to record the court-ordered judgement on the blockchain;determining that the request is associated with a court; recording thehash value of the court-ordered judgement on the blockchain; andrecording a time stamp representing a time the hash value of thecourt-ordered judgement is recorded on the blockchain.
 7. Anon-transitory, computer-readable medium storing one or moreinstructions executable by a computer system to perform operationscomprising: receiving a court-ordered judgement that specifies a debtor,a creditor, and an amount of debt owed by the debtor to the creditor;determining that the court-ordered judgement is authentic based onmatching with a hash value associated with the court-ordered judgementrecorded on a blockchain; determining a deadline of enforcing thecourt-ordered judgement; identifying one or more payment accountsassociated with the debtor; receiving an alert from a financialinstitution associated with the one or more payment accounts, whereinthe alert is triggered by a withdrawal request associated with aparticular payment account of the one or more payment accounts, andwherein the alert indicates that, after withdrawing a particular amountof the withdrawal request, a remaining balance of the particular paymentaccount is less than the amount of debt; collecting, as a collectedasset, at least a portion of the amount of debt from the one or morepayment accounts associated with the debtor, before the deadline ofenforcing the court-ordered judgement; sending the collected asset tothe creditor; and adding a record to the blockchain, wherein the recordincludes an amount of the collected asset.
 8. The non-transitory,computer-readable medium of claim 7, wherein identifying the one or morepayment accounts associated with the debtor comprises: identifying atleast one available payment account associated with the debtor; sendingat least one first request to at least one financial institutionassociated with the at least one available payment account, wherein eachfirst request of the at least one first request is used to determinewhether a corresponding available payment account of the at least oneavailable payment account has a balance that is greater than or equal tothe amount of debt; and receiving at least one first response from theat least one financial institution, wherein each first response of theat least one first response indicates either: (i) a balance of acorresponding available payment account is greater than or equal to theamount of debt, or (ii) the balance of the corresponding availablepayment account is less than the amount of debt.
 9. The non-transitory,computer-readable medium of claim 8, the operations further comprising:determining that at least two payment accounts each has a balance thatis greater than or equal to the amount of debt respectively; andrandomly selecting, as the one or more payment accounts, a paymentaccount of the at least two payment accounts.
 10. The non-transitory,computer-readable medium of claim 8, the operations further comprising:determining that none of the at least one available payment account hasa balance that is greater than or equal to the amount of debt; sendingat least one second request to the at least one financial institution,wherein each second request of the at least one second request is usedto determine whether a corresponding available payment account of the atleast one available payment account has a balance that is greater thanor equal to a particular amount that is less than the amount of debt;receiving at least one second response from the at least one financialinstitution, wherein each second response of the at least one secondresponse indicates either: (i) a balance of a corresponding availablepayment account is greater than or equal to the particular amount, or(ii) the balance of the corresponding available payment account is lessthan the particular amount; and determining, based on the at least onesecond response, the one or more payment accounts having an aggregatedbalance greater than or equal to the amount of debt.
 11. Thenon-transitory, computer-readable medium of claim 10, the operationsfurther comprising: decreasing the particular amount until the one ormore payment accounts having the aggregated balance greater than orequal to the amount of debt are identified.
 12. The non-transitory,computer-readable medium of claim 7, the operations further comprising,before receiving the court-ordered judgement: receiving a request torecord the court-ordered judgement on the blockchain; determining thatthe request is associated with a court; recording the hash value of thecourt-ordered judgement on the blockchain; and recording a time stamprepresenting a time the hash value of the court-ordered judgement isrecorded on the blockchain.
 13. A computer-implemented system,comprising: one or more computers; and one or more computer memorydevices interoperably coupled with the one or more computers and havingtangible, non-transitory, machine-readable media storing one or moreinstructions that, when executed by the one or more computers, performone or more operations comprising: receiving a court-ordered judgementthat specifies a debtor, a creditor, and an amount of debt owed by thedebtor to the creditor; determining that the court-ordered judgement isauthentic based on matching with a hash value associated with thecourt-ordered judgement recorded on a blockchain; determining a deadlineof enforcing the court-ordered judgement; identifying one or morepayment accounts associated with the debtor; receiving an alert from afinancial institution associated with the one or more payment accounts,wherein the alert is triggered by a withdrawal request associated with aparticular payment account of the one or more payment accounts, andwherein the alert indicates that, after withdrawing a particular amountof the withdrawal request, a remaining balance of the particular paymentaccount is less than the amount of debt; collecting, as a collectedasset, at least a portion of the amount of debt from the one or morepayment accounts associated with the debtor, before the deadline ofenforcing the court-ordered judgement; sending the collected asset tothe creditor; and adding a record to the blockchain, wherein the recordincludes an amount of the collected asset.
 14. The computer-implementedsystem of claim 13, wherein identifying the one or more payment accountsassociated with the debtor comprises: identifying at least one availablepayment account associated with the debtor; sending at least one firstrequest to at least one financial institution associated with the atleast one available payment account, wherein each first request of theat least one first request is used to determine whether a correspondingavailable payment account of the at least one available payment accounthas a balance that is greater than or equal to the amount of debt; andreceiving at least one first response from the at least one financialinstitution, wherein each first response of the at least one firstresponse indicates either: (i) a balance of a corresponding availablepayment account is greater than or equal to the amount of debt, or (ii)the balance of the corresponding available payment account is less thanthe amount of debt.
 15. The computer-implemented system of claim 14, theoperations further comprising: determining that at least two paymentaccounts each has a balance that is greater than or equal to the amountof debt respectively; and randomly selecting, as the one or more paymentaccounts, a payment account of the at least two payment accounts. 16.The computer-implemented system of claim 14, the operations furthercomprising: determining that none of the at least one available paymentaccount has a balance that is greater than or equal to the amount ofdebt; sending at least one second request to the at least one financialinstitution, wherein each second request of the at least one secondrequest is used to determine whether a corresponding available paymentaccount of the at least one available payment account has a balance thatis greater than or equal to a particular amount that is less than theamount of debt; receiving at least one second response from the at leastone financial institution, wherein each second response of the at leastone second response indicates either: (i) a balance of a correspondingavailable payment account is greater than or equal to the particularamount, or (ii) the balance of the corresponding available paymentaccount is less than the particular amount; and determining, based onthe at least one second response, the one or more payment accountshaving an aggregated balance greater than or equal to the amount ofdebt.
 17. The computer-implemented system of claim 16, the operationsfurther comprising: decreasing the particular amount until the one ormore payment accounts having the aggregated balance greater than orequal to the amount of debt are identified.